JPH0973173A - Resist material and resist pattern forming method - Google Patents
Resist material and resist pattern forming methodInfo
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- JPH0973173A JPH0973173A JP8050264A JP5026496A JPH0973173A JP H0973173 A JPH0973173 A JP H0973173A JP 8050264 A JP8050264 A JP 8050264A JP 5026496 A JP5026496 A JP 5026496A JP H0973173 A JPH0973173 A JP H0973173A
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Abstract
Description
【0001】[0001]
【発明の属する技術分野】本発明は、レジスト材料に関
し、さらに詳しく述べると、高解像性、高感度、そして
優れたドライエッチング耐性を有する化学増幅型レジス
ト材料に関する。本発明は、また、かかる新規なレジス
ト材料を使用したレジストパターンの形成方法に関す
る。本発明によるパターン形成方法は、レジストパター
ンの現像時にクラックの発生やパターンの剥離を低減す
るのに特に有効であるので、半導体集積回路等の半導体
装置の製造に有利に使用することができる。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a resist material, and more specifically to a chemically amplified resist material having high resolution, high sensitivity, and excellent dry etching resistance. The present invention also relates to a method for forming a resist pattern using such a novel resist material. Since the pattern forming method according to the present invention is particularly effective in reducing the occurrence of cracks and the peeling of patterns during the development of resist patterns, it can be advantageously used in the manufacture of semiconductor devices such as semiconductor integrated circuits.
【0002】[0002]
【従来の技術】近年、半導体集積回路は集積化が進んで
LSIやVLSIが実用化されており、また、これとと
もに、集積回路の最小パターンはサブミクロン領域に及
び、更に微細化する傾向にある。微細パターンの形成に
は、薄膜を形成した被処理基板上をレジストで被覆し、
選択露光を行って所望のパターンの潜像を形成した後に
現像してレジストパターンを作り、これをマスクとして
ドライエッチングを行い、その後にレジストを除去する
ことにより所望のパターンを得るリソグラフィ技術の使
用が必須である。そして、このリソグラフィに使用する
露光源として、g線(波長436nm) 、i線(波長36
5nm)の紫外線光が使用されているが、パターンの微細
化に伴い、より波長の短い遠紫外線光、真空紫外光、電
子線、X線などが光源として使用されるようになってい
る。特に最近では、エキシマレーザ(波長248nmのK
rFレーザ、波長193nmのArFレーザ)が光源とし
て注目されており、微細パターンの形成に有効であると
期待されている。なお、本願明細書では、″放射線″な
る語を用いた場合、これらの様々の光源からの光、すな
わち、紫外線、遠紫外線、真空紫外光、電子線(E
B)、X線、各種レーザ光等を意味するものとする。2. Description of the Related Art In recent years, integration of semiconductor integrated circuits has progressed, and LSIs and VLSIs have been put into practical use. At the same time, the minimum pattern of an integrated circuit has been in the submicron region and has been further miniaturized. . To form a fine pattern, cover the substrate on which the thin film is formed with a resist,
After forming a latent image of a desired pattern by performing selective exposure, it is developed to form a resist pattern, dry etching is performed using this as a mask, and then the resist is removed to use the lithography technique to obtain the desired pattern. Required. The g-line (wavelength 436 nm) and the i-line (wavelength 36
Ultraviolet light of 5 nm) is used, but with the miniaturization of patterns, far ultraviolet light, vacuum ultraviolet light, electron beams, X-rays, and the like having shorter wavelengths have been used as light sources. Particularly recently, excimer laser (K of wavelength 248 nm)
An rF laser (ArF laser having a wavelength of 193 nm) has been attracting attention as a light source, and is expected to be effective for forming a fine pattern. In this specification, when the term “radiation” is used, light from these various light sources, that is, ultraviolet rays, far ultraviolet rays, vacuum ultraviolet rays, electron beams (E
B), X-rays, various laser beams, and the like.
【0003】より短波長である遠紫外・真空紫外領域の
露光光を用いてサブミクロンのパターンを形成するに
は、用いられるレジストが、露光光の波長において透明
性に優れていることが必要であり、さらにまた、十分な
ドライエッチング耐性をもつことが求められている。こ
のようなレジストとして、本発明者らは、例えば、エス
テル部にアダマンタン骨格を有するアクリル酸エステル
又はα置換アクリル酸エステルの重合体又は共重合体か
らなることを特徴とする放射線感光材料を発明し、すで
に特許出願した(特開平4−39665号公報参照)。
また、本発明者らは、同様なレジストとして、エステル
部にノルボルナン骨格を有するアクリル酸エステル又は
α置換アクリル酸エステルの重合体又は共重合体からな
ることを特徴とする化学増幅型放射線感光材料を発明し
た(特開平5−257284号公報参照)。In order to form a submicron pattern using exposure light in the far ultraviolet / vacuum ultraviolet region, which is a shorter wavelength, it is necessary that the resist used has excellent transparency at the wavelength of the exposure light. In addition, it is required to have sufficient dry etching resistance. As such a resist, the present inventors have invented, for example, a radiation-sensitive material characterized by comprising a polymer or copolymer of an acrylic acid ester or an α-substituted acrylic acid ester having an adamantane skeleton in the ester part. Already applied for a patent (see Japanese Patent Application Laid-Open No. 4-39665).
In addition, the inventors of the present invention provide, as a similar resist, a chemically amplified radiation-sensitive material comprising a polymer or copolymer of acrylic acid ester or α-substituted acrylic acid ester having a norbornane skeleton in the ester portion. Invented (see Japanese Patent Application Laid-Open No. 5-257284).
【0004】[0004]
【発明が解決しようとする課題】本発明者らが先に発明
した化学増幅型レジスト及びそれを用いたパターン形成
方法は、各種の光源からの光、特に遠紫外・真空紫外領
域の波長をもつエキシマ光に対して高い透明性を有する
ばかりでなく、優れたドライエッチング耐性も有する。
しかし、これらのレジストは、厚膜で使用した場合や、
溶解能の高い現像液を用いて現像を行った場合など、適
用される使用条件によってクラックやパターンの剥れを
生じやすく、安定したパターニング特性を得ることがで
きないという欠点を依然として有している。このような
欠点がなぜ引き起こされるのかの正確な理由は不明であ
るけれども、レジストの骨格構造中に含まれる脂環式炭
化水素部分が、疎水性が強いうえに剛直であるため、現
像時にレジスト膜にかかる歪が大きくなることも1つの
原因となっていると理解される。SUMMARY OF THE INVENTION The chemically amplified resist and the pattern forming method using the same, which the inventors of the present invention have previously invented, have light from various light sources, particularly wavelengths in the deep ultraviolet and vacuum ultraviolet regions. Not only has high transparency to excimer light, but also excellent dry etching resistance.
However, these resists, when used in thick film,
Even when developing is performed using a developing solution having a high solubility, cracks and pattern peeling easily occur depending on the application conditions applied, and stable patterning characteristics cannot be obtained. Although the exact reason why such a defect is caused is unknown, the alicyclic hydrocarbon portion contained in the skeleton structure of the resist is highly hydrophobic and rigid, so that the resist film is not easily formed during development. It is understood that one of the causes is that the strain applied to the surface becomes large.
【0005】また、上記のような脂環式炭化水素部分が
存在することの結果、かかる化学増幅型レジストの現像
に、この技術分野で常用のアルカリ現像液を使用できな
いという欠点もある。すなわち、レジストの構造中に含
まれる脂環式炭化水素部分が、疎水性が強いので、アル
カリ現像液へのレジストの溶解を妨げていると理解され
る。なお、アルカリ現像液の使用に係わる問題を解決す
るため、本発明者らは、保護されたアルカリ可溶性基を
有しかつその保護基が酸により脱離して当該化合物をア
ルカリ可溶性とならしめる繰り返し単位を含む重合体又
は共重合体と、放射線露光により酸を発生する酸発生剤
とを含むレジストを、露光後、特定のアンモニウム化合
物又はモルフォリン化合物の水溶液又はアルコール溶液
を含む現像液で現像することを特徴とするレジストパタ
ーンの形成方法を見い出し、特許出願した(平成7年2
月10日出願の特願平7−23053号の明細書を参照
されたい)。Further, as a result of the presence of the alicyclic hydrocarbon moiety as described above, there is also a drawback in that an alkaline developer commonly used in this technical field cannot be used for developing such a chemically amplified resist. That is, it is understood that the alicyclic hydrocarbon portion contained in the structure of the resist has strong hydrophobicity and thus prevents dissolution of the resist in the alkali developing solution. In order to solve the problem associated with the use of an alkaline developer, the present inventors have found that a repeating unit having a protected alkali-soluble group and eliminating the protecting group with an acid makes the compound alkali-soluble. After exposure, a resist containing a polymer or a copolymer containing the above and an acid generator that generates an acid by radiation exposure is developed with a developer containing an aqueous solution or alcohol solution of a specific ammonium compound or morpholine compound. We found a method of forming a resist pattern characterized by
Please refer to the specification of Japanese Patent Application No. 7-23053 filed on Oct. 10).
【0006】さらに、上記したようなレジストは、通
常、被エッチング層を有する基板との密着性が悪く、基
板上のレジスト膜が現像時に基板から剥離することがあ
ったり、また、焼き付けようとする回路パターンが遮光
されるようにできた露光マスクを介して露光を行った場
合に、所望のマスクパターンより若干大きい形状のレジ
ストパターンができあがることがあった。したがって、
マスクパターンにより、レジストパターンを精確かつ忠
実に再現できるようなレジスト材料を提供することが望
まれている。Further, the resist as described above usually has poor adhesion to the substrate having the layer to be etched, the resist film on the substrate may be peeled off from the substrate during development, or is intended to be baked. When exposure is performed through an exposure mask that is designed to shield the circuit pattern from light, a resist pattern having a shape slightly larger than a desired mask pattern may be formed. Therefore,
It is desired to provide a resist material that can accurately and faithfully reproduce a resist pattern by using a mask pattern.
【0007】上記の説明から理解されるように、化学増
幅型レジストとそれを用いたパターン形成方法の改良に
当たっては、通常、レジスト材料そのものを改良するア
プローチと、レジストプロセスにおいて用いられる現像
液を改良するアプローチの2つのアプローチがとられて
いる。本発明は、諸般の条件等を考慮して、レジスト材
料そのものを改良しようとするものである。As can be understood from the above description, in improving the chemically amplified resist and the pattern forming method using the same, usually, the approach for improving the resist material itself and the developing solution used in the resist process are improved. There are two approaches taken. The present invention aims to improve the resist material itself in consideration of various conditions.
【0008】本発明の1つの目的は、したがって、エキ
シマ光を含めた各種の放射線に対して高い透明性を有
し、優れたドライエッチング耐性を有し、現像時のクラ
ックの発生やパターンの剥離を低減した、すなわち、安
定したパターニング特性を奏する、改良された化学増幅
型レジストを提供することにある。本発明のもう1つの
目的は、基板との密着性が良好で、マスクパターンに対
応するパターンを忠実に再現可能な改良された化学増幅
型レジストを提供することにある。Accordingly, one object of the present invention is, therefore, to have high transparency to various radiations including excimer light, to have excellent dry etching resistance, to generate cracks during development and to remove patterns. It is an object of the present invention to provide an improved chemically amplified resist which has reduced patterning, that is, exhibits stable patterning characteristics. Another object of the present invention is to provide an improved chemically amplified resist which has good adhesion to a substrate and can faithfully reproduce a pattern corresponding to a mask pattern.
【0009】また、本発明のもう1つの目的は、そのよ
うな化学増幅型レジストを使用した、標準アルカリ現像
液で現像を行い得る改良されたレジストパターンの形成
方法を提供することにある。Another object of the present invention is to provide an improved method for forming a resist pattern, which uses such a chemically amplified resist and can be developed with a standard alkaline developer.
【0010】[0010]
【課題を解決するための手段】本発明は、1つの面にお
いて、次式(I)〜(VI)のいずれかにより表される脂
環式炭化水素基含有部分:The present invention, in one aspect, comprises an alicyclic hydrocarbon group-containing moiety represented by any of the following formulas (I) to (VI):
【0011】[0011]
【化24】 Embedded image
【0012】(上式において、RI は、1〜4個の炭素
原子を有する直鎖もしくは分岐鎖のアルキル基を表し、
置換もしくは非置換のいずれであってもよく、そしてZ
は、記載の炭素原子とともに脂環式炭化水素基を完成す
るのに必要な複数個の原子を表す)(In the above formula, R I represents a linear or branched alkyl group having 1 to 4 carbon atoms,
May be substituted or unsubstituted, and Z
Represents a plurality of atoms necessary for completing the alicyclic hydrocarbon group together with the indicated carbon atom)
【0013】[0013]
【化25】 Embedded image
【0014】(上式において、RIIは、同一もしくは異
なっていてもよく、1〜4個の炭素原子を有する置換も
しくは非置換の直鎖もしくは分岐鎖のアルキル基又は脂
環式脂環式炭化水素基を表し、但し、RIIの少なくとも
1個は脂環式炭化水素基である)(In the above formula, R II may be the same or different and is a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms or an alicyclic alicyclic carbon group. Represents a hydrogen group, provided that at least one of R II is an alicyclic hydrocarbon group)
【0015】[0015]
【化26】 [Chemical formula 26]
【0016】(上式において、RIIは前記定義に同じで
ある)(In the above formula, R II is as defined above)
【0017】[0017]
【化27】 Embedded image
【0018】(上式において、RIII は、同一もしくは
異なっていてもよく、プロトン、1〜4個の炭素原子を
有する置換もしくは非置換の直鎖もしくは分岐鎖のアル
キル基又は脂環式炭化水素基を表し、但し、RIII の少
なくとも1個は脂環式炭化水素基であり、また、式中、
非二重結合の炭素原子に結合した2個のRIII のうち少
なくとも1個は、1〜4個の炭素原子を有する置換もし
くは非置換の直鎖もしくは分岐鎖のアルキル基又は脂環
式炭化水素基である)(In the above formula, R III may be the same or different, and is a proton, a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms, or an alicyclic hydrocarbon. Represents a group, provided that at least one of R III is an alicyclic hydrocarbon group, and
At least one of the two R IIIs bonded to the carbon atom of the non-double bond is a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms or an alicyclic hydrocarbon. Is the basis)
【0019】[0019]
【化28】 Embedded image
【0020】(上式において、RIIは前記定義に同じで
ある)(In the above formula, R II is as defined above)
【0021】[0021]
【化29】 [Chemical 29]
【0022】(上式において、RI 及びZは前記定義に
同じである)で保護されたアルカリ可溶性基を有しかつ
前記アルカリ可溶性基が酸により脱離して当該化合物を
アルカリ可溶性とならしめる構造単位を含む酸感応性化
合物と、放射線露光により酸を発生する酸発生剤とを含
んでなることを特徴とするレジスト材料を提供する。A structure having an alkali-soluble group protected by R 1 and Z (wherein R I and Z are the same as defined above), and the alkali-soluble group is eliminated by an acid to render the compound alkali-soluble. A resist material comprising an acid-sensitive compound containing a unit and an acid generator that generates an acid upon exposure to radiation.
【0023】本発明は、そのもう1つの面において、上
記した式(I)〜(VI)のいずれかにより表される脂環
式炭化水素基含有部分で保護されたアルカリ可溶性基を
有しかつ前記アルカリ可溶性基が酸により脱離して当該
化合物をアルカリ可溶性とならしめる構造単位を含む酸
感応性化合物と、放射線露光により酸を発生する酸発生
剤とを含むレジスト材料を被処理基板上に塗布し、前記
被処理基板上のレジスト膜を前記酸発生剤からの酸の発
生を惹起し得る放射線に選択的に露光し、そして露光後
のレジスト膜のポストベーク後、前記露光工程において
形成された潜像を現像すること、を含んでなることを特
徴とするレジストパターンの形成方法を提供する。In another of its aspects, the present invention has an alkali-soluble group protected by an alicyclic hydrocarbon group-containing moiety represented by any of the above formulas (I) to (VI), and A resist material containing an acid-sensitive compound containing a structural unit that makes the compound alkali-soluble by leaving the alkali-soluble group by an acid and an acid generator that generates an acid upon exposure to radiation is coated on a substrate to be treated. Then, the resist film on the substrate to be processed is selectively exposed to radiation capable of inducing generation of acid from the acid generator, and after the resist film is post-baked after exposure, the resist film is formed in the exposure step. There is provided a method for forming a resist pattern, which comprises developing a latent image.
【0024】[0024]
【発明の実施の形態】本発明は、上記したように、前式
(I)〜(VI)のいずれかにより表される脂環式炭化水
素基含有部分で保護されたアルカリ可溶性基を有しかつ
前記アルカリ可溶性基が酸により脱離して当該化合物を
アルカリ可溶性とならしめる構造単位を含む酸感応性化
合物と、放射線露光により酸を発生する酸発生剤とを含
むレジスト材料にある。BEST MODE FOR CARRYING OUT THE INVENTION As described above, the present invention has an alkali-soluble group protected by an alicyclic hydrocarbon group-containing moiety represented by any of the above formulas (I) to (VI). Further, there is provided a resist material comprising an acid-sensitive compound containing a structural unit capable of eliminating the alkali-soluble group by an acid to make the compound alkali-soluble, and an acid generator which generates an acid upon exposure to radiation.
【0025】上式(I)において、RI は、好ましく
は、置換もしくは非置換のいずれであってもよい、1〜
4個の炭素原子を有する直鎖もしくは分岐鎖のアルキル
基、例えばメチル基又はエチル基であるが、これは、炭
素原子の数がさらに増加した場合、疎水性が強くなると
いう点では注目に値するというものの、基の脱離を満足
に達成し得ないなどの不都合がでてくるからである。ま
た、かかるアルキル基が置換されている場合、適当な置
換基は、例えば、ハロゲン、例えば塩素、フッ素、沃素
などである。アルカリ可溶性基の安定性などの面から、
極性の強い置換基の使用は回避することが望ましい。ま
た、このアルキル基についての規定は、他の式において
RII又はRIII によって規定されるアルキル基について
も、基本的に同様に適用することができる。本発明によ
るレジスト材料において、その主たる1成分である酸感
応性化合物の構造単位中に含まれるべきアルカリ可溶性
基は、この技術分野において周知のいろいろな基を包含
するというものの、一般的には、カルボン酸基、スルホ
ン酸基、アミド基、イミド基、フェノール基、酸無水物
基、チオール基、ラクトン酸エステル基(α−α,β−
ジメチル−γ−ブチロラクトン基)、アザラクトン基、
カーボネート基、オキサゾン基、ピロリドン基、ヒドロ
キシオキシム基などであり、好ましくはカルボン酸基、
スルホン酸基、アミド基、イミド基、そしてフェノール
基である。In the above formula (I), R I is preferably substituted or unsubstituted, 1 to
Straight-chain or branched-chain alkyl groups with 4 carbon atoms, for example methyl or ethyl groups, which are notable in that they become more hydrophobic as the number of carbon atoms increases further. However, there is a problem that the elimination of the group cannot be satisfactorily achieved. Also, when such an alkyl group is substituted, suitable substituents are, for example, halogen, such as chlorine, fluorine, iodine and the like. From the viewpoint of stability of alkali-soluble group,
It is desirable to avoid the use of strongly polar substituents. Moreover, the definition about the alkyl group can be basically similarly applied to the alkyl group defined by R II or R III in other formulas. In the resist material according to the present invention, the alkali-soluble group to be contained in the structural unit of the acid-sensitive compound which is one of the main components includes various groups well known in the technical field, but generally, Carboxylic acid group, sulfonic acid group, amide group, imide group, phenol group, acid anhydride group, thiol group, lactone acid ester group (α-α, β-
Dimethyl-γ-butyrolactone group), azalactone group,
Carbonate group, oxazone group, pyrrolidone group, hydroxyoxime group and the like, preferably a carboxylic acid group,
Sulfonic acid groups, amide groups, imide groups, and phenol groups.
【0026】また、本発明のレジスト材料では、上記の
ようなアルカリ可溶性基が脂環式炭化水素基含有部分に
よって保護されている。かかる保護されたアルカリ可溶
性基は、好ましくは、次式(VII )〜(XI)により表さ
れるカルボン酸:Further, in the resist material of the present invention, the above alkali-soluble group is protected by the alicyclic hydrocarbon group-containing portion. The protected alkali-soluble group is preferably a carboxylic acid represented by the following formulas (VII) to (XI):
【0027】[0027]
【化30】 Embedded image
【0028】[0028]
【化31】 [Chemical 31]
【0029】[0029]
【化32】 Embedded image
【0030】[0030]
【化33】 [Chemical 33]
【0031】[0031]
【化34】 Embedded image
【0032】(式中、RI 、RII及びRIII ならびにZ
は、それぞれ、前記定義に同じである)、次式(XII )
により表されるイミド基:(Wherein R I , R II and R III and Z
Are the same as defined above, respectively, and the following formula (XII)
An imide group represented by:
【0033】[0033]
【化35】 Embedded image
【0034】(式中、Zは前記定義に同じである)又は
次式(XIII)により表されるフェノール基:(Wherein Z is as defined above) or a phenol group represented by the following formula (XIII):
【0035】[0035]
【化36】 Embedded image
【0036】(式中、Zは前記定義に同じである)であ
る。また、前記アルカリ可溶性基中に含まれる脂環式炭
化水素基は、化学の分野で公知のいろいろな基を包含
し、また、それらの基は必要に応じて置換されていても
よいというものの、好ましくは、以下に詳しく説明する
ように、複数個の環構造を有するかもしくは縮合環を有
している。前記脂環式炭化水素基は、特に好ましくは、
アダマンタン又はその誘導体である。Where Z is as defined above. The alicyclic hydrocarbon group contained in the alkali-soluble group includes various groups known in the field of chemistry, and those groups may be optionally substituted, Preferably, as described in detail below, it has a plurality of ring structures or a fused ring. The alicyclic hydrocarbon group is particularly preferably
It is adamantane or its derivative.
【0037】本発明において用いられる、併用される酸
発生剤から発生せしめられた酸に対して感応性を有する
酸感応性化合物は、記載の条件を満たす限りにおいて、
低分子量の化合物から高分子量の化合物まで、広範な化
合物を包含し、また、これらの化合物は、単独で使用し
てもよく、さもなければ、2種類もしくはそれ以上の化
合物を混合して使用してもよい。かかる酸感応性化合物
は、大きく分けて、前記構造単位を繰り返し単位として
含む重合体又は共重合体、そして低分子量の非重合化合
物である。かかる酸感応性化合物は、それが重合体又は
共重合体の形をとる場合、低分子量から高分子量までの
広い範囲の分子量を有することができ、また、好ましく
は、アクリル酸エステル及びその誘導体、イタコン酸エ
ステル及びその誘導体、フマル酸エステル及びその誘導
体ならびにスチレン置換体及びその誘導体からなる群か
ら選ばれる繰り返し単位を単独もしくは組み合わせて有
している。また、前記酸感応性化合物が非重合化合物の
形をとる場合には、所期のレジスト特性を得るため、そ
の化合物と組み合わせて任意のアルカリ可溶性の重合体
又は共重合体を使用することが必要である。The acid-sensitive compound used in the present invention, which is sensitive to the acid generated from the acid generator used in combination, can be any compound as long as the conditions described above are satisfied.
It covers a wide range of compounds, from low molecular weight compounds to high molecular weight compounds, and these compounds may be used alone or else may be used as a mixture of two or more compounds. May be. Such acid-sensitive compounds are broadly classified into polymers or copolymers containing the above structural unit as a repeating unit, and low molecular weight non-polymerized compounds. Such an acid-sensitive compound, when it takes the form of a polymer or a copolymer, can have a wide range of molecular weights from low molecular weight to high molecular weight, and is preferably an acrylic acid ester and its derivative, It has repeating units selected from the group consisting of itaconic acid ester and its derivative, fumaric acid ester and its derivative, styrene-substituted compound and its derivative, alone or in combination. When the acid-sensitive compound is in the form of a non-polymerized compound, it is necessary to use an arbitrary alkali-soluble polymer or copolymer in combination with the compound in order to obtain desired resist characteristics. It is.
【0038】本発明の酸感応性化合物は、それと組み合
わせて、1種類もしくはそれ以上の同様な酸感応性化合
物を追加的に有することができる。かかる場合に適当な
追加の酸感応性化合物としては、以下に列挙するものに
限定されないけれども、3級炭素エステル、3−オキソ
エステル、アセタールのエステル、カルボキシエーテル
などを挙げることができる。また、かかる追加の酸感応
性化合物は、好ましくは、以下に列挙するようなアルカ
リ可溶性基を含有することができる:カルボン酸基、ス
ルホン酸基、アミド基、イミド基、フェノール基、酸無
水物基、チオール基、ラクトン酸エステル基(α−α,
β−ジメチル−γ−ブチロラクトン基)、アザラクトン
基、カーボネート基、オキサゾン基、ピロリドン基、ヒ
ドロキシオキシム基、ニトリル基、ニトロ基、アルデヒ
ド基、アセチル基、ヒドロキシル基、チオエーテル基な
ど。The acid-sensitive compounds of the present invention can additionally have one or more similar acid-sensitive compounds in combination therewith. Suitable additional acid-sensitive compounds in such cases include, but are not limited to, those listed below, including tertiary carbon esters, 3-oxoesters, acetal esters, carboxy ethers, and the like. Also, such additional acid-sensitive compounds may preferably contain alkali-soluble groups as listed below: carboxylic acid groups, sulfonic acid groups, amide groups, imide groups, phenolic groups, acid anhydrides. Group, thiol group, lactone acid ester group (α-α,
β-dimethyl-γ-butyrolactone group), azalactone group, carbonate group, oxazone group, pyrrolidone group, hydroxyoxime group, nitrile group, nitro group, aldehyde group, acetyl group, hydroxyl group, thioether group and the like.
【0039】化学増幅型レジスト材料において、もしも
その構造中に脂環式炭化水素基が含まれているとする
と、その強い疎水性のため、そのレジスト材料を露光後
にアルカリ水溶液で現像する段階で、露光部のアルカリ
水溶液への溶解が抑止されるものと考えられる。そこ
で、レジスト構造中に含めるべき脱保護基(保護された
アルカリ可溶性基であって、酸によりレジスト構造から
脱離可能な基)として、脂環式基を有するものを用い
て、露光及びPEB(露光後ベーク;Post Exp
osure Baking)により脱離させ、露光部よ
り脂環式基を除去することが好ましい。ところが、脂環
式基は、環構造を有するために、結合の角度が固定され
ており、その基の脱離後に二重結合を有する生成物を形
成することが困難であり、また、このために、容易に脱
離反応を生じなかった。 本発明者らは、この問題を解
決するため、上記したように、レジスト構造中に含まれ
る脱保護基の一部分に、前式(I)により表される、脂
環式基を有しかつその環骨格を構成する炭素原子の1個
が適当な低級アルキル基で置換された部分を導入するこ
とにより、該脱保護基をエステル構造とすることが有効
であることを見い出した。すなわち、脱保護基をエステ
ル構造とすることにより、その基の脱離を容易にするこ
とが可能となった。このことは、以下の説明によって本
発明を束縛しようとするものではないけれども、基の脱
離時に形成されると考えられる二重結合が、“結合の歪
み”が小さい環の外側に生成することが可能であること
に由来するものと、予想される。In the chemically amplified resist material, if the structure contains an alicyclic hydrocarbon group, its strong hydrophobicity makes it possible to develop the resist material in an aqueous alkaline solution after exposure. It is considered that dissolution of the exposed area in the alkaline aqueous solution is suppressed. Therefore, as a deprotecting group (a protected alkali-soluble group that can be removed from the resist structure by an acid) to be contained in the resist structure, one having an alicyclic group is used to perform exposure and PEB ( Post-exposure bake; Post Exp
It is preferable that the alicyclic group is removed from the exposed portion by desorbing the alicyclic group by exposure baking). However, since the alicyclic group has a ring structure, the bond angle is fixed, and it is difficult to form a product having a double bond after elimination of the group. Moreover, the elimination reaction did not easily occur. In order to solve this problem, the present inventors, as described above, have an alicyclic group represented by the above formula (I) in a part of the deprotecting group contained in the resist structure and It has been found that it is effective to make the deprotecting group an ester structure by introducing a moiety in which one of the carbon atoms constituting the ring skeleton is substituted with an appropriate lower alkyl group. That is, by making the deprotecting group an ester structure, it became possible to facilitate the elimination of the group. This is not meant to constrain the invention by the following description, but it is believed that double bonds, which are believed to be formed upon removal of the group, are formed outside the ring where "bond strain" is small. It is expected that it will be possible.
【0040】こうして、前式(I)により表される構造
を有するレジスト材料は、露光により発生したプロトン
酸を触媒として脱離反応を生じ、カルボン酸あるいはそ
の類似物を生成するとともに、露光部の脂環式基の部分
が除去される。このため、レジスト材料の露光部では、
脂環式基による溶解禁止効果がなくなり、アルカリ水溶
液に容易に溶解可能となる。結果として、レジスト材料
の現像がスムーズに進行し、所期の安定したパターニン
グ特性を得ることができる。Thus, the resist material having the structure represented by the above formula (I) undergoes an elimination reaction using the protonic acid generated by exposure as a catalyst to generate a carboxylic acid or its analogue, and at the same time The portion of the alicyclic group is removed. Therefore, in the exposed part of the resist material,
The alicyclic group has no effect of inhibiting dissolution, and can be easily dissolved in an alkaline aqueous solution. As a result, the development of the resist material proceeds smoothly, and desired stable patterning characteristics can be obtained.
【0041】また、脂環式炭化水素基が環構造を形成す
る炭素と直接にエステルを形成している化学増幅型レジ
ストでは、脂環式炭化水素基に起因する剛直性を十分に
低減することができないと考えられる。このことが、レ
ジスト膜の膜厚が厚くなるなどして現像中に歪みを生じ
やすくなる場合において、クラックや剥がれを生じる一
因となっていると予測できる。本発明者らは、この問題
を解決するため、上記したように、レジスト構造中に前
式(II)〜(VI)により表される脱保護構造を導入する
のが有効であるということを見い出した。すなわち、こ
の脱保護構造では、脂環式基が含まれるけれども、環構
造が直接にエステルを形成しているのではなく、少なく
とも1個以上の原子を介してエステルを形成している。
この場合に介在させるべき原子としては、炭素原子がも
っとも一般的であるけれども、酸素、窒素あるいは硫黄
等、脱離機能を損なうものでなければ、限定されるもの
ではない。このことは、以下の説明によって本発明を束
縛しようとするものではないけれども、環構造と直接に
エステルを形成していない脱保護基とし、脂環式炭化水
素基を主鎖から遠ざけることにより剛直性を緩和するこ
とが可能になったものと、予想される。Further, in the chemically amplified resist in which the alicyclic hydrocarbon group directly forms an ester with the carbon forming the ring structure, the rigidity due to the alicyclic hydrocarbon group should be sufficiently reduced. It seems that you cannot do it. It can be predicted that this is one of the causes of cracks and peeling when strain is likely to occur during development due to an increase in the thickness of the resist film. In order to solve this problem, the present inventors have found that it is effective to introduce the deprotection structure represented by the above formulas (II) to (VI) into the resist structure as described above. It was That is, in this deprotected structure, although the alicyclic group is included, the ring structure does not directly form an ester, but forms an ester through at least one atom.
In this case, the carbon atom is the most common as an intervening atom, but it is not limited as long as it does not impair the elimination function, such as oxygen, nitrogen or sulfur. Although this is not intended to limit the present invention by the following description, it is a deprotecting group that does not form an ester directly with the ring structure, and the alicyclic hydrocarbon group is made rigid by moving it away from the main chain. It is expected that it has become possible to ease gender.
【0042】こうして、前式(II)〜(VI)により表さ
れる構造を有するレジスト材料は、露光により発生した
プロトン酸を触媒として脱離反応を生じ、カルボン酸あ
るいはその類似物を生成するとともに、露光部の脂環式
基の部分が除去される。このため、レジスト材料の露光
部では、脂環式基による溶解禁止効果がなくなり、アル
カリ水溶液に容易に溶解可能となる。結果として、レジ
スト材料の現像がスムーズに進行し、所期の安定したパ
ターニング特性を得ることができる。これまでは、前式
(I)により表される構造を有するレジスト材料の場合
に同様である。加えて、この特定のレジスト材料では、
上記したように脂環式炭化水素基が主鎖から離れている
ので、得られるレジスト膜の剛直性が低減され、現像時
にレジスト膜に生じる歪みの影響が小さくなる。このた
め、現像時のクラックや剥がれを生じにくくなり、結果
として安定したパターニング特性を得ることができる。Thus, the resist material having the structure represented by the above formulas (II) to (VI) causes an elimination reaction by using the protonic acid generated by exposure as a catalyst to form a carboxylic acid or its analogue. , The alicyclic group portion of the exposed portion is removed. For this reason, in the exposed portion of the resist material, the effect of inhibiting dissolution by the alicyclic group is eliminated, and the resist material can be easily dissolved in an aqueous alkaline solution. As a result, the development of the resist material proceeds smoothly, and desired stable patterning characteristics can be obtained. Up to now, the same applies to the case of the resist material having the structure represented by the above formula (I). In addition, with this particular resist material,
Since the alicyclic hydrocarbon group is distant from the main chain as described above, the rigidity of the obtained resist film is reduced, and the influence of strain generated in the resist film during development is reduced. For this reason, cracks and peeling are less likely to occur during development, and as a result, stable patterning characteristics can be obtained.
【0043】本発明による化学増幅型レジストは、上記
した通り、保護されたアルカリ可溶性基が酸により脱離
してアルカリ可溶性となる酸感応性化合物、好ましく
は、重合体又は共重合体(ここで、“共重合体”とは、
三成分もしくはそれよりも多成分の共重合体も含む)あ
るいは非重合化合物と、酸発生剤とを組み合わせて有す
る化学増幅型レジストである。以下、かかる化学増幅型
レジストとその調製、そしてそれを用いたレジストパタ
ーンの形成をそれらの好ましい態様を参照して詳細に説
明する。なお、本発明は、以下に記載する態様にのみ限
定されるものではないことを理解されたい。As described above, the chemically amplified resist according to the present invention is an acid-sensitive compound, preferably a polymer or copolymer (wherein a protected alkali-soluble group is eliminated by an acid to become alkali-soluble). What is a "copolymer"?
A chemically amplified resist having a combination of a three-component or multi-component copolymer) or a non-polymerized compound and an acid generator. Hereinafter, such a chemically amplified resist, its preparation, and formation of a resist pattern using the same will be described in detail with reference to preferred embodiments thereof. It should be understood that the present invention is not limited only to the embodiments described below.
【0044】本発明による化学増幅型レジストにおい
て、その主たる1成分である酸感応性化合物の構造単位
中に含まれる保護されたアルカリ可溶性基は、好ましく
は、カルボン酸基、スルホン酸基、アミド基、イミド基
及びフェノール基からなる群から選ばれる一員であり、
さらに好ましくは、前式(VII )〜(XI)により表され
るカルボン酸、前次式(XII )により表されるイミド
基、そして前式(XIII)により表されるフェノール基で
ある。In the chemically amplified resist according to the present invention, the protected alkali-soluble group contained in the structural unit of the acid-sensitive compound which is one of the main components is preferably a carboxylic acid group, a sulfonic acid group or an amide group. , A member selected from the group consisting of an imide group and a phenol group,
More preferably, it is a carboxylic acid represented by the above formulas (VII) to (XI), an imide group represented by the following formula (XII), and a phenol group represented by the above formula (XIII).
【0045】例えば、保護されたアルカリ可溶性基とし
てのカルボン酸基は、酸によりその保護基が脱離してカ
ルボン酸を生じるユニットであり、例えば、t−ブチル
エステル、t−アミルエステル、α,α−ジメチルベン
ジルエステル等の3級炭素エステル、テトラヒドロピラ
ニルエステル等のアセタールからなるエステル、3−オ
キシシクロヘキシルエステル等のβ−オキシケトンから
なるエステル、その他をあげることができる。For example, a carboxylic acid group serving as a protected alkali-soluble group is a unit which produces a carboxylic acid upon elimination of the protecting group from an acid, and examples thereof include t-butyl ester, t-amyl ester, α, α. -A tertiary carbon ester such as dimethylbenzyl ester, an acetal ester such as tetrahydropyranyl ester, a β-oxyketone ester such as 3-oxycyclohexyl ester, and the like.
【0046】これらのカルボン酸基及びその他のアルカ
リ可溶性基のための保護基は、以下に列挙するものに限
定されるわけではないけれども、好ましくは、3級炭化
水素基、例えばt−ブチル基など、又はβ−オキシケト
ン基、例えば3−オキソシクロヘキシル基、環状β−ヒ
ドロキシケトン基、例えばメバロニックラクトン基な
ど、である。Protecting groups for these carboxylic acid groups and other alkali-soluble groups are not limited to those listed below, but are preferably tertiary hydrocarbon groups such as t-butyl groups. Or a β-oxyketone group such as a 3-oxocyclohexyl group, a cyclic β-hydroxyketone group such as a mevalonic lactone group, and the like.
【0047】また、本発明の化学増幅型レジストにおい
て用いられる酸感応性化合物は、好ましくは、トリアル
キルカルビノールから形成されるエステル、アセタール
から形成されるエステル、β−オキシケトンから形成さ
れるエステル、α−オキシアルケンあるいはα−オキシ
シクロアルケンから形成されるエステル、その他をその
構造単位中に含むことができる。The acid-sensitive compound used in the chemically amplified resist of the present invention is preferably an ester formed from trialkylcarbinol, an ester formed from acetal, an ester formed from β-oxyketone, An ester formed from an α-oxyalkene or an α-oxycycloalkene, and the like can be included in the structural unit.
【0048】また、前記アルカリ可溶性基中に含まれる
脂環式炭化水素基は、化学増幅型レジストの分野で公知
のいろいろな基を包含する。適当な脂環式炭化水素基
は、その一例を示すと、次のような化合物を骨格とする
ものである。 (1)アダマンタン及びその誘導体 (2)ノルボルナン及びその誘導体 (3)パーヒドロアントラセン及びその誘導体 (4)パーヒドロナフタレン及びその誘導体 (5)トリシクロ〔5.2.1.02,6 〕デカン及びそ
の誘導体 (6)ビシクロヘキサン及びその誘導体 (7)スピロ〔4,4〕ノナン及びその誘導体 (8)スピロ〔4,5〕デカン及びその誘導体 これらの化合物は、それぞれ、次のような構造式で表さ
れる:The alicyclic hydrocarbon group contained in the alkali-soluble group includes various groups known in the field of chemically amplified resist. Suitable alicyclic hydrocarbon groups are, for example, those having the following compounds as a skeleton. (1) Adamantane and its derivatives (2) Norbornane and its derivatives (3) Perhydroanthracene and its derivatives (4) Perhydronaphthalene and its derivatives (5) Tricyclo [5.2.1.0 2,6 ] decane and Derivatives thereof (6) Bicyclohexane and its derivatives (7) Spiro [4,4] nonane and its derivatives (8) Spiro [4,5] decane and its derivatives These compounds have the following structural formulas, respectively. expressed:
【0049】[0049]
【化37】 Embedded image
【0050】本発明の実施に当たって、脂環式炭化水素
としては、上記したように複数個の環構造を有するかも
しくは縮合環を有しているものが好ましく、単環である
シクロヘキシル基等では十分なドライエッチング耐性を
得ることができない。また、これらの化合物のうちで、
従来のノボラック系レジストと同等かもしくはそれ以上
のドライエッチング耐性を得るには、アダマンタン等の
縮合環が、特に好ましい。In the practice of the present invention, the alicyclic hydrocarbon is preferably one having a plurality of ring structures or a condensed ring as described above, and a monocyclic cyclohexyl group is sufficient. Dry etching resistance cannot be obtained. Also among these compounds,
A condensed ring of adamantane or the like is particularly preferable in order to obtain a dry etching resistance equal to or higher than that of the conventional novolac-based resist.
【0051】本発明による化学増幅型レジストおいて、
それに含まれる酸感応性化合物は、好ましくは、重合体
又は共重合体の形をとることができる。ここで用いられ
る酸感応性重合体又は共重合体は、多種多様なもののな
かから任意に選択して使用することができる。酸感応性
重合体又は共重合体は、以下に列挙するものに限定され
るものではないけれども、好ましくは、アクリル酸エス
テル及びその誘導体、イタコン酸エステル及びその誘導
体、フマル酸エステル及びその誘導体ならびにスチレン
置換体及びその誘導体からなる群から選ばれる繰り返し
単位(構造単位)を単独もしくは組み合わせて有するも
のである。それというのも、これらの繰り返し単位は、
重合体又は共重合体の調製及びその塗布性の面でその他
の重合体又は共重合体よりも有利であるからである。In the chemically amplified resist according to the present invention,
The acid-sensitive compound contained therein can preferably take the form of a polymer or a copolymer. The acid-sensitive polymer or copolymer used here can be arbitrarily selected from various types and used. The acid-sensitive polymer or copolymer is not limited to those listed below, but preferably, acrylic acid ester and its derivative, itaconic acid ester and its derivative, fumaric acid ester and its derivative, and styrene. It has repeating units (structural units) selected from the group consisting of substitution products and derivatives thereof alone or in combination. Because these repeating units are
This is because it is more advantageous than other polymers or copolymers in terms of preparation of the polymer or copolymer and its coatability.
【0052】また、酸感応性共重合体は、必要に応じ
て、上記したような繰り返し単位に組み合わせて、以下
に列挙するものに限定されるわけではないけれども、そ
の他の繰り返し単位、例えば、アクリロニトリル、オレ
フィン、ジエン又はこれらの誘導体を用いて調製しても
よい。本発明の酸感応性重合体又は共重合体において、
満足すべき密着性を得るためには、強い極性を有する繰
り返し単位を使用することが好ましい。特に、かかる重
合体又は共重合体は、必須の構成要素であるところのア
ルカリ可溶性基を有することに加えて、自体アルカリ可
溶性である繰り返し単位を有していれば、アルカリ可溶
性基に由来する少量のカルボン酸等の生成で現像可能と
なることが期待され、さらに好ましい。The acid-sensitive copolymer is not limited to those listed below in combination with the repeating unit as described above, if necessary, but other repeating units such as acrylonitrile may be used. , Olefins, dienes or their derivatives. In the acid-sensitive polymer or copolymer of the present invention,
In order to obtain satisfactory adhesion, it is preferable to use a repeating unit having a strong polarity. In particular, such a polymer or copolymer, in addition to having an alkali-soluble group which is an essential component, if it has a repeating unit which is itself alkali-soluble, a small amount derived from the alkali-soluble group It is expected that development will be possible by the generation of carboxylic acid and the like, which is more preferable.
【0053】本発明によれば、したがって、レジスト材
料の1成分としての酸感応性化合物が、共重合体の形を
とっており、そしてその繰り返し単位が、上記した構造
単位に加えて、アルカリ可溶性基を側鎖に有する繰り返
し単位及び(又は)前記酸発生剤から生じる酸により脱
離可能な追加の保護されたアルカリ可溶性基を側鎖に有
する繰り返し単位を含むことを特徴とするレジスト材料
が提供される。According to the invention, therefore, the acid-sensitive compound as a component of the resist material is in the form of a copolymer, the repeating units of which, in addition to the structural units mentioned above, are alkali-soluble. A resist material comprising a repeating unit having a group in a side chain and / or an additional protected alkali-soluble group capable of leaving by an acid generated from the acid generator in a side chain is provided. To be done.
【0054】かかるレジスト材料の共重合体は、好まし
くは、次式(XIV )又は(XV)により表される構造単位
を有することができる。The copolymer of the resist material may preferably have a structural unit represented by the following formula (XIV) or (XV).
【0055】[0055]
【化38】 Embedded image
【0056】[0056]
【化39】 Embedded image
【0057】上式において、Rは、同一もしくは異なっ
ていてもよく、水素、ハロゲン又は1〜4個の炭素原子
を有する置換もしくは非置換の直鎖もしくは分岐鎖のア
ルキル基を表し、RI は、1〜4個の炭素原子を有する
直鎖もしくは分岐鎖のアルキル基を表し、置換もしくは
非置換のいずれであってもよく、Aは、酸により脱離可
能な保護基を表し、そしてZは、記載の炭素原子ととも
に脂環式炭化水素基を完成するのに必要な複数個の原子
を表す。In the above formula, R may be the same or different and represents hydrogen, halogen or a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms, and R I is , A linear or branched alkyl group having 1 to 4 carbon atoms, which may be substituted or unsubstituted, A represents an acid-eliminating protecting group, and Z represents , Represents a plurality of atoms necessary to complete an alicyclic hydrocarbon group together with the described carbon atom.
【0058】前式(XIV )の構造単位は、アダマンタン
やノルボルナンなどの脂環式骨格を有していて酸発生剤
から生じる酸により脱離する保護基と、アルカリ可溶な
カルボン酸基とを組み合わせて含ませた例である。レジ
ストの構造中に酸性の基が存在するので、露光後の露光
部のアルカリ現像液への溶け出しがスムーズになる。ま
た、その酸性基の含有量をコントロールすれば、現在標
準化されているアルカリ現像液(2.38%テトラメチ
ルアンモニウムヒドロキシド水溶液)でも現像可能であ
る。この場合、カルボン酸を含むユニットのレジスト中
の含有量は、5モル%以上2モル%未満であるのが望ま
しい。The structural unit of the above formula (XIV) has an alicyclic skeleton such as adamantane or norbornane and has a protecting group capable of leaving by an acid generated from an acid generator and an alkali-soluble carboxylic acid group. This is an example of including them in combination. Since an acidic group is present in the structure of the resist, the exposed portion after the exposure is smoothly dissolved into the alkali developing solution. Further, if the content of the acidic group is controlled, development can be performed even with an alkali developer (a 2.38% aqueous solution of tetramethylammonium hydroxide) which is currently standardized. In this case, the content of the unit containing the carboxylic acid in the resist is preferably 5 mol% or more and less than 2 mol%.
【0059】また、前式(XV)の構造単位は、アダマン
タンやノルボルナンなどの脂環式骨格を有していて酸発
生剤から生じる酸により脱離する保護基、同じく酸によ
り脱離するけれども通常の保護基(但し、波長193nm
のArFエキシマレーザを用いたリソグラフィを意図し
ているような場合には、保護基中に芳香族環が含まれな
いことが好ましい)、そしてアルカリ可溶なカルボン酸
基を組み合わせて含ませた例である。このようなレジス
ト構造では、脱離が起こらない場合でも、レジストがア
ルカリに溶解可能であるので、露光後の露光部のアルカ
リ現像液への溶け出しがスムーズになるという効果があ
る。The structural unit of the above formula (XV) has an alicyclic skeleton such as adamantane or norbornane and is a protecting group which is eliminated by an acid generated from an acid generator. Protecting group (however, wavelength 193nm
In the case where lithography using an ArF excimer laser is intended, it is preferable that an aromatic ring is not included in the protective group.) And an example in which an alkali-soluble carboxylic acid group is included in combination It is. In such a resist structure, the resist can be dissolved in alkali even when no desorption occurs, so that there is an effect that the exposed portion after exposure to the alkali developer is smoothly dissolved.
【0060】ところで、前記した次式(XIV )又は(X
V)中の置換基RI は、前記したものと同様に、メチル
基、エチル基、それらのハロゲン化(塩素化、臭素化
等)物などであることができる。また、酸により脱離可
能な保護基Aは、上記したように通常の保護基、例え
ば、4級炭素基あるいはβ−オキシケトン基、例えばt
−ブチル基、t−アミル基、3−オキシシクロヘキシル
基などであることができる。また、Zにより完成される
脂環式炭化水素基は、好ましくは、先に一般式で示した
ような、アダマンタン及びその誘導体、ノルボルナン及
びその誘導体、パーヒドロアントラセン及びその誘導
体、パーヒドロナフタレン及びその誘導体、トリシクロ
〔5.2.1.02,6 〕デカン及びその誘導体、ビシク
ロヘキサン及びその誘導体、スピロ〔4,4〕ノナン及
びその誘導体、スピロ〔4,5〕デカン及びその誘導体
などである。By the way, the following formula (XIV) or (X
The substituent R I in V) may be a methyl group, an ethyl group, a halogenated (chlorinated, brominated, etc.) product thereof, and the like, as described above. In addition, the protecting group A which can be removed by an acid is, as described above, a usual protecting group such as a quaternary carbon group or a β-oxyketone group such as t.
-Butyl group, t-amyl group, 3-oxycyclohexyl group and the like. The alicyclic hydrocarbon group completed by Z is preferably adamantane and its derivatives, norbornane and its derivatives, perhydroanthracene and its derivatives, perhydronaphthalene and its Derivatives, tricyclo [5.2.1.0 2,6 ] decane and its derivatives, bicyclohexane and its derivatives, spiro [4,4] nonane and its derivatives, spiro [4,5] decane and its derivatives, etc. .
【0061】特にアルカリ可溶性基がカルボン酸である
場合を参照して本発明において有用である酸感応性重合
体又は共重合体をさらに具体的に説明すると、次の通り
である。酸感応性重合体は、好ましくは、次式(XVI )
により表されるメタ(アクリレート)重合体である。The acid-sensitive polymer or copolymer useful in the present invention will be described more specifically with reference to the case where the alkali-soluble group is a carboxylic acid. The acid-sensitive polymer preferably has the following formula (XVI)
Is a meta (acrylate) polymer represented by
【0062】[0062]
【化40】 [Chemical 40]
【0063】上式において、Rは、プロトン(水素)、
ハロゲン、置換もしくは非置換のアルキル基、例えばメ
チル基あるいはエチル基、メチロール基などを表し、A
は、前式(I)〜(VI)の部分に相当し、例えば、保護
基、好ましくは4級炭素基あるいはβ−オキシケトン
基、例えばt−ブチル基、t−アミル基、3−オキシシ
クロヘキシル基などで保護された脂環式炭化水素基、好
ましくはアダマンチル、ノルボルニル、シクロヘキシ
ル、トリシクロ〔5.2.1.0〕デカンなどを表し、
そしてnは任意の正の整数を表す。In the above formula, R is a proton (hydrogen),
Represents a halogen, a substituted or unsubstituted alkyl group such as a methyl group, an ethyl group or a methylol group,
Corresponds to the moiety of the above formulas (I) to (VI), and is, for example, a protecting group, preferably a quaternary carbon group or a β-oxyketone group such as t-butyl group, t-amyl group, 3-oxycyclohexyl group. Represents an alicyclic hydrocarbon group protected by, for example, preferably adamantyl, norbornyl, cyclohexyl, tricyclo [5.2.1.0] decane, and the like,
And n represents an arbitrary positive integer.
【0064】また、酸感応性共重合体は、好ましくは、
次式(XVII)及び(XVIII )により表されるメタ(アク
リレート)共重合体である。なお、メタ(アクリレー
ト)三成分共重合体もこれに準じて構成することができ
る。The acid-sensitive copolymer is preferably
It is a meth (acrylate) copolymer represented by the following formulas (XVII) and (XVIII). In addition, a meth (acrylate) ternary copolymer can be also configured according to this.
【0065】[0065]
【化41】 Embedded image
【0066】[0066]
【化42】 Embedded image
【0067】上式において、R、A及びnは、それぞ
れ、前記定義に同じであり、Yは、任意の置換基、好ま
しくは、例えば、アルキル基、例えばt−ブチル基な
ど、エーテル基、例えばフェノキシ基など、脂環式基、
例えばアダマンチル、ノルボルニル、シクロヘキシル、
トリシクロ〔5.2.1.0〕デカンなど、あるいは次
式の基:In the above formula, R, A and n are respectively as defined above, and Y is an optional substituent, preferably an alkyl group such as t-butyl group, an ether group such as t-butyl group. Alicyclic groups such as phenoxy group,
For example, adamantyl, norbornyl, cyclohexyl,
Tricyclo [5.2.1.0] decane or the like, or a group represented by the following formula:
【0068】[0068]
【化43】 Embedded image
【0069】などを表し、式中、R1、R2及びR3は、それ
ぞれ、水素、置換もしくは非置換のアルキル基又はアル
キレン基、例えばメチル基、エチル基、メチレン基な
ど、その他を表し、そしてBは、任意の置換基、好まし
くは、例えば、カルボキシル基、あるいは次式の基:Wherein R 1 , R 2 and R 3 each represent hydrogen, a substituted or unsubstituted alkyl group or an alkylene group, such as a methyl group, an ethyl group, a methylene group, etc., B is an optional substituent, preferably, for example, a carboxyl group or a group of the following formula:
【0070】[0070]
【化44】 Embedded image
【0071】などを表し、式中、置換基D中のR4は、水
素又は置換もしくは非置換のアルキル基、例えばメチル
基あるいはエチル基であり、そしてl及びmは、それぞ
れ、任意の正の整数を表す。本発明において有利に用い
ることのできる酸感応性共重合体は、さらに具体的に
は、以下のものに限定されるわけではないけれども、次
のようなものを包含する。なお、式中のm及びnは、そ
れぞれ、前記定義に同じである。Wherein R 4 in substituent D is hydrogen or a substituted or unsubstituted alkyl group such as a methyl group or an ethyl group, and 1 and m are each of any positive value. Represents an integer. Acid-sensitive copolymers that can be advantageously used in the present invention include, but are not limited to the following, more specifically, the following. Note that m and n in the formula are the same as defined above.
【0072】[0072]
【化45】 Embedded image
【0073】[0073]
【化46】 Embedded image
【0074】[0074]
【化47】 Embedded image
【0075】[0075]
【化48】 Embedded image
【0076】[0076]
【化49】 Embedded image
【0077】[0077]
【化50】 Embedded image
【0078】[0078]
【化51】 [Chemical 51]
【0079】[0079]
【化52】 Embedded image
【0080】[0080]
【化53】 Embedded image
【0081】[0081]
【化54】 Embedded image
【0082】[0082]
【化55】 Embedded image
【0083】[0083]
【化56】 Embedded image
【0084】[0084]
【化57】 Embedded image
【0085】[0085]
【化58】 Embedded image
【0086】前記した酸感応性重合体又は共重合体は、
必要に応じて、アルカリ可溶性の重合体又は共重合体、
例えば、ノボラック樹脂、フェノール樹脂、イミド樹
脂、カルボン酸含有樹脂、その他を追加的に含有してい
てもよい。さらにまた、本発明の実施に当たっては、上
記したような酸感応性重合体又は共重合体に代えて、重
合せしめられていない低分子の化合物(本願明細書で
は、特に、「非重合化合物」と呼ぶ)を同一の目的に使
用することができる。ここで用いられる非重合化合物
は、前記した通り、保護されたアルカリ可溶性基が酸に
より脱離してアルカリ可溶性となる酸感応性化合物であ
り、その分子中に前式(I)〜(VI)で表される部分を
含有する保護されたアルカリ可溶性基を有しかつ記載の
挙動を呈する限りにおいて特に限定されるものではな
い。一般的には、かかる非重合化合物は、脂環式の環骨
格、ベンゼン環等の芳香族環の環骨格、アルキル骨格等
を有していて、それらの骨格の一部が前式(I)〜(V
I)で表される部分を含有する基で置換されているもの
である。好ましい非重合化合物の例を一般式で示すと、
以下に列挙するものに限定されるわけではないけれど
も、次のような化合物を包含する。なお、下式におい
て、RI 、RII、Z及びnは、それぞれ、前記した定義
に同じである。The above-mentioned acid-sensitive polymer or copolymer is
If necessary, an alkali-soluble polymer or copolymer,
For example, a novolac resin, a phenol resin, an imide resin, a carboxylic acid-containing resin, and the like may be additionally contained. Furthermore, in carrying out the present invention, instead of the acid-sensitive polymer or copolymer as described above, a low-molecular compound that has not been polymerized (in the present specification, particularly, "non-polymerized compound") Can be used for the same purpose. The non-polymerizable compound used here is an acid-sensitive compound in which the protected alkali-soluble group is eliminated by an acid to become alkali-soluble, as described above, and has the above formulas (I) to (VI) in its molecule. It is not particularly limited as long as it has a protected alkali-soluble group containing the moiety shown and exhibits the described behavior. Generally, such a non-polymerized compound has an alicyclic ring skeleton, a ring skeleton of an aromatic ring such as a benzene ring, an alkyl skeleton, and the like, and a part of these skeletons is represented by the formula (I). ~ (V
It is substituted with a group containing the moiety represented by I). When an example of a preferable non-polymerized compound is represented by the general formula,
Although not limited to those listed below, the following compounds are included. In the formula below, R I , R II , Z and n are the same as defined above.
【0087】[0087]
【化59】 Embedded image
【0088】[0088]
【化60】 Embedded image
【0089】[0089]
【化61】 [Chemical formula 61]
【0090】[0090]
【化62】 Embedded image
【0091】[0091]
【化63】 Embedded image
【0092】[0092]
【化64】 Embedded image
【0093】[0093]
【化65】 Embedded image
【0094】[0094]
【化66】 Embedded image
【0095】また、これらの非重合化合物は、必要に応
じて、前式(I)〜(VI)で表される部分を含有する基
に加えて、その他の、その保護基が酸により脱離してカ
ルボン酸等を生じるユニット、例えば、t−ブチルエス
テル、t−アミルエステル、α,α−ジメチルベンジル
エステル等の3級炭素エステル、テトラヒドロピラニル
エステル等のアセタールからなるエステル、3−オキシ
シクロヘキシルエステル等のβ−オキシケトンからなる
エステル、その他を有していてもよい。In addition, these non-polymerizable compounds may contain, in addition to the group containing the moiety represented by the above formulas (I) to (VI), other protective groups thereof may be eliminated by an acid, if necessary. Units that generate carboxylic acid and the like, for example, tertiary carbon esters such as t-butyl ester, t-amyl ester, α, α-dimethylbenzyl ester, acetal ester such as tetrahydropyranyl ester, 3-oxycyclohexyl ester, etc. It may have an ester composed of β-oxyketone, and the like.
【0096】これらの非重合化合物は、それらの単独で
は所期のレジスト特性を奏することができないので、ア
ルカリ可溶性の重合体又は共重合体を併用することが必
要である。ここで使用することのできるアルカリ可溶性
の重合体又は共重合体は、以下に記載するものに限定さ
れるわけではないけれども、例えば、ノボラック樹脂、
フェノール樹脂、イミド樹脂、カルボン酸含有樹脂、そ
の他を包含する。なお、非重合化合物とアルカリ可溶性
重合体又は共重合体の混合比は、使用する化合物等の特
性、所望とするレジスト特性、その他のファクターに応
じて広い範囲で変更することができる。Since these non-polymerized compounds cannot exhibit the desired resist properties by themselves, it is necessary to use an alkali-soluble polymer or copolymer together. The alkali-soluble polymer or copolymer that can be used here is not limited to those described below, for example, a novolak resin,
Includes phenolic resins, imide resins, carboxylic acid containing resins, and others. The mixing ratio between the non-polymerized compound and the alkali-soluble polymer or copolymer can be changed in a wide range according to the properties of the compound used, the desired resist properties, and other factors.
【0097】また、本発明の化学増幅型レジストにおい
て上記したような酸感応性重合体又は共重合体あるいは
非重合化合物と組み合わせて用いられる酸発生剤は、レ
ジストの化学において一般的に用いられている酸発生
剤、すなわち、紫外線、遠紫外線、真空紫外線、電子
線、X線、レーザ光などの放射線の照射によりプロトン
酸を生じる物質であることができる。本発明の実施にお
いて適当な酸発生剤は、以下に列挙するものに限定され
ないけれども、次のようなものを包含する。 (1)次式により表されるジアゾニウム塩: Ar−N2 + X- (上式において、Arは、置換もしくは非置換の芳香族
基、例えばフェニル基など、又は脂環式基を表し、そし
てXは、ハロゲン、例えばCl、Br、IあるいはF、
BF4 、BF6 、PF6、AsF6 、SbF6 、CF3
SO3 、ClO4 又は有機スルホン酸アニオンなどを表
す) (2)次式により表されるヨードニウム塩:The acid generator used in the chemically amplified resist of the present invention in combination with the acid-sensitive polymer or copolymer or non-polymerized compound as described above is generally used in resist chemistry. The acid generator may be a substance that generates a protonic acid upon irradiation with radiation such as ultraviolet rays, far ultraviolet rays, vacuum ultraviolet rays, electron beams, X-rays, and laser light. Suitable acid generators in the practice of the present invention include, but are not limited to, those listed below. (1) diazonium salt represented by the formula: Ar-N 2 + X - in (the above formula, Ar is a substituted or unsubstituted aromatic group, such as a phenyl group, or an alicyclic group, and X is halogen such as Cl, Br, I or F,
BF 4 , BF 6 , PF 6 , AsF 6 , SbF 6 , CF 3
SO 3, represents and ClO 4 or an organic sulfonic acid anion) (2) iodonium salt represented by the following formula:
【0098】[0098]
【化67】 Embedded image
【0099】(上式において、Ar及びXは、前記定義
に同じである) (3)次式により表されるスルホニウム塩:(In the above formula, Ar and X are the same as defined above.) (3) Sulfonium salt represented by the following formula:
【0100】[0100]
【化68】 Embedded image
【0101】[0101]
【化69】 Embedded image
【0102】[0102]
【化70】 Embedded image
【0103】[0103]
【化71】 Embedded image
【0104】[0104]
【化72】 Embedded image
【0105】[0105]
【化73】 Embedded image
【0106】(上式において、R、R1、R2、R3、Ar及
びXは、それぞれ、前記定義に同じであり、例えば、R
はメチル基などであり、R1、R2及びR3はフェニル基など
であり、そしてtBuは、t−ブチル基である) (4)次式により表されるスルホン酸エステル:(In the above formula, R, R 1 , R 2 , R 3 , Ar and X are the same as defined above, for example, R
Is a methyl group or the like, R 1 , R 2 and R 3 are phenyl groups or the like, and tBu is a t-butyl group) (4) A sulfonate represented by the following formula:
【0107】[0107]
【化74】 Embedded image
【0108】(上式において、Ar及びRは、前記定義
に同じである) (5)次式により表されるオキサアゾール誘導体:(In the above formula, Ar and R are the same as defined above.) (5) Oxazole derivative represented by the following formula:
【0109】[0109]
【化75】 Embedded image
【0110】(上式において、Xは前記定義に同じであ
り、但し、−CX3 基の1つは置換もしくは非置換のア
リール基又はアルケニル基であってもよい) (6)次式により表されるs−トリアジン誘導体:(In the above formula, X has the same meaning as defined above, provided that one of the -CX 3 groups may be a substituted or unsubstituted aryl group or alkenyl group.) (6) S-triazine derivatives:
【0111】[0111]
【化76】 [Chemical 76]
【0112】(上式において、Xは前記定義に同じであ
り、但し、−CX3 基の1つは置換もしくは非置換のア
リール基又はアルケニル基であってもよい) (7)次式により表されるジスルホン誘導体: Ar−SO2 −SO2 −Ar (上式において、Arは前記定義に同じである) (8)次式により表されるイミド化合物:(In the above formula, X has the same definition as described above, provided that one of the -CX 3 groups may be a substituted or unsubstituted aryl group or alkenyl group) (7) it is disulfone derivatives: Ar-SO 2 -SO 2 -Ar ( in the above formula, Ar are as defined above) (8) imide represented by the formula compound:
【0113】[0113]
【化77】 Embedded image
【0114】(上式において、Xは前記定義に同じであ
る) (9)その他、例えばオキシムスルホネート、ジアゾナ
フトキノン、ベンゾイントシレートなど。 これらの酸発生剤は、さらに具体的にいくつかの例を示
すと、次のような化合物である。トリフェニルスルホニ
ウムヘキサフルオロアンチモネート:(In the above formula, X has the same meaning as defined above.) (9) Others such as oxime sulfonate, diazonaphthoquinone and benzoin tosylate. More specifically, some examples of these acid generators are the following compounds. Triphenylsulfonium hexafluoroantimonate:
【0115】[0115]
【化78】 Embedded image
【0116】トリフェニルホスホニウムヘキサフルオロ
ホスフェート:Triphenylphosphonium hexafluorophosphate:
【0117】[0117]
【化79】 Embedded image
【0118】ジフェニルヨードヘキサフルオロホスフェ
ート:Diphenyliodohexafluorophosphate:
【0119】[0119]
【化80】 Embedded image
【0120】ベンゾイントシレート:Benzoin tosylate:
【0121】[0121]
【化81】 Embedded image
【0122】本発明を実施するに当って、上記したよう
な酸感応性化合物と酸発生剤とから化学増幅型レジスト
を調製する。例えば、かかるレジストの調製は、レジス
トの化学において一般的に行われている技法を使用して
常法に従って、レジスト溶液の形で調製することができ
る。例えば、レジストを構成する酸感応性化合物が上記
したような重合体又は共重合体である場合、その重合体
又は共重合体を形成するための選ばれた単量体を適当な
重合開始剤の存在において重合せしめ、次いで得られた
重合体又は共重合体の溶液に酸発生剤を添加してレジス
ト溶液とすることができる。ここで使用する重合条件及
び重合開始剤は、常用されている広い範囲のもののなか
から任意に選択して使用することができる。例えば、適
当な重合開始剤の一例として、次のようなものを挙げる
ことができる。 AIBN(アゾイソブチロニトリル):In carrying out the present invention, a chemically amplified resist is prepared from the above-mentioned acid-sensitive compound and acid generator. For example, such a resist can be prepared in the form of a resist solution according to a conventional method using a technique generally used in resist chemistry. For example, when the acid-sensitive compound constituting the resist is a polymer or a copolymer as described above, the selected monomer for forming the polymer or the copolymer is a suitable polymerization initiator. Polymerization can be carried out in the presence, and then an acid generator can be added to the resulting polymer or copolymer solution to give a resist solution. The polymerization conditions and polymerization initiator used here can be arbitrarily selected from a wide range of commonly used ones. For example, the following can be mentioned as an example of a suitable polymerization initiator. AIBN (azoisobutyronitrile):
【0123】[0123]
【化82】 [Chemical formula 82]
【0124】MAIB(ジメチル−2,2−アゾイソビ
スブチラート):MAIB (Dimethyl-2,2-azoisobisbutyrate):
【0125】[0125]
【化83】 [Chemical 83]
【0126】化学増幅型レジストの調製において、酸感
応性化合物に添加する酸発生剤の量は、広い範囲にわた
って変更することができ、一般には約1〜30重量%、
好ましくは約1〜15重量%である。また、そのような
レジストの溶液の調製に用いる溶媒は、レジストの種
類、塗布条件、その他のファクタに応じていろいろに変
更し得るというものの、好ましくは、例えばシクロヘキ
サン、プロピレングリコールモノメチルエーテルアセテ
ート(PGMEA)、乳酸エチルなどの有機溶媒であ
る。In the preparation of the chemically amplified resist, the amount of the acid generator added to the acid sensitive compound can be varied over a wide range, and is generally about 1 to 30% by weight.
It is preferably about 1 to 15% by weight. Further, the solvent used for preparing such a resist solution can be variously changed depending on the type of the resist, coating conditions, and other factors, but preferably, for example, cyclohexane, propylene glycol monomethyl ether acetate (PGMEA). , An organic solvent such as ethyl lactate.
【0127】本発明によるレジストパターンの形成方法
は、任意のいろいろな工程を経て実施することができる
というものの、好ましくは、次のようにして実施するこ
とができる。最初に、上記のようにして調製した化学増
幅型レジストの溶液を被処理基板上に塗布する。ここで
使用する被処理基板は、半導体装置及びその他の装置に
おいて通常用いられているいかなる基板であってもよ
く、具体的には、シリコン、酸化膜、ポリシリコン、窒
化膜、アルミニウムなどをあげることができる。これら
の基板は、すでに回路が作りこまれていても、あるいは
作りこまれていなくてもよい。これらの基板は、場合に
よっては、レジストとの密着性を向上させるために、例
えばヘキサメチルジシラザン(HMDS)などのような
密着促進剤で前処理しておくことが好ましい。The method for forming a resist pattern according to the present invention can be carried out through various arbitrary steps, but preferably it can be carried out as follows. First, the solution of the chemically amplified resist prepared as described above is applied on the substrate to be processed. The substrate to be processed used here may be any substrate normally used in semiconductor devices and other devices, and specifically, silicon, oxide film, polysilicon, nitride film, aluminum, etc. may be mentioned. You can These substrates may or may not have the circuitry already built. In some cases, these substrates are preferably pretreated with an adhesion promoter such as hexamethyldisilazane (HMDS) in order to improve the adhesion to the resist.
【0128】レジスト溶液の塗布は、スピンコータ、デ
ィップコータ、ローラコータなどのような常用の塗布装
置を使用して行うことができる。形成されるレジスト膜
の膜厚は、そのレジスト膜の使途などのファクターに応
じて広く変更し得るというものの、通常約0.3〜2.
0μmの範囲である。次いで、必要に応じて、放射線を
選択的に露光する前に、上記工程で形成されたレジスト
膜を約60〜150℃、好ましくは約60〜100℃の
温度で約60〜180秒間にわたってプリベークする。
このプリベークには、例えばホットプレートのような加
熱手段を用いることができる。The coating of the resist solution can be carried out by using a conventional coating device such as a spin coater, a dip coater, a roller coater or the like. Although the thickness of the formed resist film can be widely varied depending on factors such as the use of the resist film, it is usually about 0.3 to 2.
The range is 0 μm. Then, if necessary, before selectively exposing to radiation, the resist film formed in the above step is prebaked at a temperature of about 60 to 150 ° C., preferably about 60 to 100 ° C. for about 60 to 180 seconds. .
For this prebaking, a heating means such as a hot plate can be used.
【0129】また、もしもレジスト膜の上にさらにトッ
プコート膜(保護膜)を施すような場合には、例えば、
オレフィン樹脂の溶液をスピンコート法によりレジスト
膜上に塗布し、100℃前後の温度でベーキングを行う
ことによって、トップコート膜とすることができる。レ
ジスト膜の形成及び任意にプリベーク後、そのレジスト
膜を常用の露光装置で放射線に選択露光する。適当な露
光装置は、市販の紫外線(遠紫外線・真空紫外線)露光
装置、X線露光装置、電子ビーム露光装置、エキシマス
テッパ、その他である。露光条件は、その都度、適当な
条件を選択することができる。この選択露光の結果、レ
ジスト膜に含まれる酸発生剤から酸が発生せしめられ
る。If a top coat film (protective film) is further formed on the resist film, for example,
A top coat film can be obtained by applying a solution of an olefin resin onto a resist film by spin coating and performing baking at a temperature of about 100 ° C. After forming the resist film and optionally prebaking, the resist film is selectively exposed to radiation by a conventional exposure apparatus. Suitable exposure apparatuses are commercially available ultraviolet (far ultraviolet / vacuum ultraviolet) exposure apparatuses, X-ray exposure apparatuses, electron beam exposure apparatuses, excimer steppers, and the like. As the exposure condition, an appropriate condition can be selected each time. As a result of this selective exposure, an acid is generated from the acid generator contained in the resist film.
【0130】次いで、露光後のレジスト膜を露光後ベー
ク(PEB)することによって、酸を触媒とした保護基
の脱離反応を生じさせる。この露光後ベークは、先のプ
リベークと同様にして行うことができる。例えば、ベー
ク温度は約60〜150℃、好ましくは約100〜15
0℃である。なお、トップコート膜を併用している場合
には、この露光後ベークの後であって現像の前、例えば
有機溶剤によってそれを剥離除去する。Then, the resist film after exposure is subjected to post-exposure baking (PEB) to cause an acid-catalyzed elimination reaction of the protective group. This post-exposure bake can be performed in the same manner as the previous pre-bake. For example, the baking temperature is about 60-150 ° C, preferably about 100-15.
0 ° C. When a top coat film is used in combination, after the post-exposure bake and before the development, it is removed by, for example, an organic solvent.
【0131】露光後ベークを完了した後、露光後のレジ
スト膜を常法に従って液体現像する。ここで使用する現
像液は、この技術分野で一般的に用いられている現像液
のなかから、適当なものを任意に選択することができ
る。とりわけ好ましい現像液は、先に引用した特開平7
−23053号明細書のなかで提案されているように、
現像剤としての、次式のアンモニウム化合物:After the post-exposure bake is completed, the post-exposure resist film is liquid-developed by a conventional method. As the developer used here, an appropriate one can be arbitrarily selected from developers commonly used in this technical field. A particularly preferred developer is the above-cited JP-A-7
As proposed in -23053,
Ammonium compounds of the formula as developers:
【0132】[0132]
【化84】 Embedded image
【0133】(式中、R1、R2、R3及びR4は、それぞれ、
同一もしくは異なっていてもよく、1〜6個の炭素原子
を有する置換もしくは非置換のアルキル基を表す)、次
式のモルフォリン化合物:(Wherein R 1 , R 2 , R 3 and R 4 are respectively
Which may be the same or different and represent a substituted or unsubstituted alkyl group having 1 to 6 carbon atoms), a morpholine compound of the following formula:
【0134】[0134]
【化85】 Embedded image
【0135】又はその混合物の水溶液又はアルコール溶
液を含む現像液である。現像剤としてのアンモニウム化
合物の好ましい例は、以下に列挙するものに限定される
わけではないけれども、テトラメチルアンモニウムハイ
ドロキシド(TMAH)、テトラエチルアンモニウムハ
イドロキシド(TEAH)、テトラプロピルアンモニウ
ムハイドロキジド(TPAH)、テトラブチルアンモニ
ウムハイドロキシド(TBAH)、などを包含する。A developing solution containing an aqueous solution or an alcohol solution of a mixture thereof. Preferred examples of the ammonium compound as the developer are not limited to those listed below, but include tetramethylammonium hydroxide (TMAH), tetraethylammonium hydroxide (TEAH), and tetrapropylammonium hydroxide (TPAH). ), Tetrabutylammonium hydroxide (TBAH), and the like.
【0136】これらの現像剤を水に溶解するかもしく
は、例えばメタノール、エタール、イソプロピルアルコ
ール等のアルコールに溶解して現像液となす。溶解する
現像剤の濃度は、広く変更することができるけれども、
一般的に約0.1〜15重量%の範囲、好ましくは約
0.1〜10重量%の範囲である。現像時間は、これも
特に限定されるわけではないけれども、一般的に約1〜
5分間の範囲、好ましくは約1〜3分間の範囲である。
現像の結果、レジスト膜の露光域が溶解除去せしめられ
て、所望とするレジストパターンを得ることができる。
最後に、得られたレジストパターンも常法に従って純水
でリンスし、そして乾燥する。These developers are dissolved in water or in alcohols such as methanol, etal and isopropyl alcohol to prepare a developing solution. Although the concentration of the dissolving developer can vary widely,
Generally, it will be in the range of about 0.1 to 15% by weight, preferably about 0.1 to 10% by weight. The development time is not particularly limited, but is generally about 1 to 1.
It is in the range of 5 minutes, preferably in the range of about 1 to 3 minutes.
As a result of development, the exposed area of the resist film is dissolved and removed, and a desired resist pattern can be obtained.
Finally, the obtained resist pattern is also rinsed with pure water according to a conventional method, and dried.
【0137】以上の説明及び下記の実施例から理解され
るように、本発明では、化学増幅型レジスト材料とし
て、その構造中に前式(I)〜(VI)により表される、
脂環式基を有しかつその環骨格を構成する炭素原子の1
個が適当な低級アルキル基で置換された部分を有する脱
保護基あるいはその環骨格が他原子を1個以上経由して
エステル結合している脱保護基を具えた化合物を用いる
ことにより、露光部の溶解性が増大し、現像がスムーズ
に進行するため、レジスト膜の剥がれやクラックを低減
し、安定したパターニング特性を得ることができ、ある
いは、脂環式炭化水素基に起因する剛直性を低減し、安
定したパターニング特性を得ることができる。As can be understood from the above description and the following examples, in the present invention, the chemically amplified resist material is represented by the formulas (I) to (VI) in the structure thereof.
1 of carbon atoms having an alicyclic group and constituting the ring skeleton
By using a compound having a deprotecting group having a moiety in which each is substituted with an appropriate lower alkyl group or a compound having a deprotecting group whose ring skeleton is ester-bonded through one or more other atoms, Solubility increases and development progresses smoothly, so peeling and cracking of the resist film can be reduced and stable patterning characteristics can be obtained, or the rigidity due to alicyclic hydrocarbon groups can be reduced. In addition, stable patterning characteristics can be obtained.
【0138】本発明において用いられる脱保護基は、脂
環式ユニットと脱保護ユニットとからなる化学レジスト
において特に著しい効果を奏することが判明しているけ
れども、他のレジストの場合においても満足し得る効果
を奏することができる。なお、特に顕著な効果を奏する
レジストとしては、前記したように、アダマンタン及び
その誘導体、ノルボルナン及びその誘導体、トリシクロ
〔5.2.1.02,6〕デカン及びその誘導体などの脂
環式基を含む樹脂を挙げることができる。The deprotecting group used in the present invention has been found to be particularly effective in a chemical resist consisting of an alicyclic unit and a deprotecting unit, but it can be satisfied in the case of other resists. It is possible to exert an effect. As described above, examples of the resist having a particularly remarkable effect include alicyclic groups such as adamantane and its derivatives, norbornane and its derivatives, tricyclo [5.2.1.0 2,6 ] decane and its derivatives. And a resin containing:
【0139】[0139]
【実施例】次いで、本発明をそのいくつかの実施例を参
照して説明する。なお、下記の実施例はほんの一例であ
って、これによって本発明が限定されるものではないこ
とを理解されたい。例1 メタクリル酸2−メチルアダマンチルモノマとアルリル
酸t−ブチルモノマを4:6の割合で重合容器に仕込
み、2モル/Lの1,4−ジオキサン溶液とした。この
1,4−ジオキサン溶液に重合開始剤、AIBN(アゾ
イソブチロニトリル)を5モル%の量で添加し、80℃
で約8時間にわたって重合させた。重合の完結後、n−
ヘキサンを沈殿剤として精製を行った。次式により表さ
れる2−メチルアダマンチルメタクリレート/t−ブチ
ルアクリレート共重合体が得られた。Next, the present invention will be described with reference to some embodiments. It should be understood that the following embodiments are merely examples and the present invention is not limited thereto. Example 1 2-Methyladamantyl methacrylate monomer and t-butyl monomer acrylate were charged into a polymerization vessel at a ratio of 4: 6 to prepare a 2 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN (azoisobutyronitrile), was added to this 1,4-dioxane solution in an amount of 5 mol%, and the mixture was heated to 80 ° C.
Was allowed to polymerize for about 8 hours. After completion of the polymerization, n-
Purification was performed using hexane as a precipitant. A 2-methyladamantyl methacrylate / t-butyl acrylate copolymer represented by the following formula was obtained.
【0140】[0140]
【化86】 Embedded image
【0141】得られた共重合体は、組成比(m:n)が
49:51、重量平均分子量(Mw)が6890、そし
て分散度(Mw/Mn)が1.89であった。例2 前記例1において調製した2−メチルアダマンチルメタ
クリレート/t−ブチルアクリレート共重合体に15重
量%の酸発生剤、トリフェニルスルホニウムヘキサフル
オロアンチモネートを添加し、シクロヘキサノンに溶解
した。得られたレジスト溶液を、ヘキサメチルジシラザ
ン(HMDS)で前処理したシリコン基板上に膜厚0.
7μmでスピンコートし、ホットプレート上で100℃
で100秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 49:51, a weight average molecular weight (Mw) of 6890, and a dispersity (Mw / Mn) of 1.89. Example 2 To the 2-methyladamantyl methacrylate / t-butyl acrylate copolymer prepared in Example 1 above, 15% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added and dissolved in cyclohexanone. The obtained resist solution was applied on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a film thickness of 0.
Spin coated at 7μm and 100 ℃ on a hot plate
And prebaked for 100 seconds.
【0142】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を130℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは21.2mJ/cm2 であり、解像力は
0.275μm L&S(ライン・アンド・スペース)
であった。例3 前記例2に記載の手法を繰り返した。但し、本例では、
現像液として、0.27NのTMAH水溶液に代えて同
濃度(0.27N)のテトラブチルアンモニウムハイド
ロキシド(TBAH)水溶液を使用した。前記例2の場
合と同様の満足し得るレジストパターンが、Eth=2
8.6mJ/cm2 で解像力=0.275μm L&Sで得
られた。例4 (比較例) 前記例1及び例2に記載の手法を繰り返した。但し、本
例では、比較のため、前記例1に記載の手法で次式によ
り表されかつその組成比(m:n)が53:47、重量
平均分子量(Mw)が3830、そして分散度(Mw/
Mn)が2.1のアダマンチルメタクリレート/t−ブ
チルアクリレート共重合体:After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 6 ° C. at 130 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 21.2 mJ / cm 2 , and the resolution is 0.275 μm L & S (line and space).
Met. Example 3 The procedure described in Example 2 above was repeated. However, in this example,
As the developing solution, a tetrabutylammonium hydroxide (TBAH) aqueous solution having the same concentration (0.27N) was used instead of the 0.27N TMAH aqueous solution. The same satisfactory resist pattern as in the case of Example 2 above is Eth = 2
It was obtained at a resolution of 0.275 μm L & S at 8.6 mJ / cm 2 . Example 4 (Comparative Example) The procedure described in Examples 1 and 2 was repeated. However, in this example, for comparison, the composition ratio (m: n) is represented by the following formula by the method described in Example 1 above, the composition ratio (m: n) is 53:47, the weight average molecular weight (Mw) is 3830, and the dispersity ( Mw /
Mn) adamantyl methacrylate / t-butyl acrylate copolymer with 2.1:
【0143】[0143]
【化87】 Embedded image
【0144】を調製した。得られた共重合体を使用して
前記例2に記載のようにレジストプロセスを実施したけ
れども、まったくパターンが得られなかった。例5 アクリル酸2−メチルアダマンチルモノマを重合容器に
仕込み、2モル/Lのトルエン溶液とした。このトルエ
ン溶液に重合開始剤、AIBNを2モル%の量で添加
し、80℃で約8時間にわたって重合させた。重合の完
結後、メタノールを沈殿剤として精製を行った。次式に
より表される2−メチルアダマンチルアクリレート重合
体(式中のnは、下記の分子量を得るのに必要な繰り返
し単位の数である)が得られた。Was prepared. A resist process was carried out as described in Example 2 above using the resulting copolymer, but no pattern was obtained. Example 5 2-Methyladamantyl acrylate monomer was charged into a polymerization vessel to prepare a 2 mol / L toluene solution. A polymerization initiator, AIBN, was added to this toluene solution in an amount of 2 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, methanol was used as a precipitant for purification. A 2-methyladamantyl acrylate polymer represented by the following formula (where n is the number of repeating units necessary for obtaining the following molecular weight) was obtained.
【0145】[0145]
【化88】 Embedded image
【0146】得られた重合体は、重量平均分子量(M
w)が8950、そして分散度(Mw/Mn)が1.8
であった。例6 前記例5において調製した2−メチルアダマンチルアク
リレート重合体に15重量%の酸発生剤、トリフェニル
スルホニウムヘキサフルオロアンチモネートを添加し、
シクロヘキサノンに溶解した。得られたレジスト溶液
を、ヘキサメチルジシラザン(HMDS)で前処理した
シリコン基板上に膜厚0.7μmでスピンコートし、ホ
ットプレート上で100℃で100秒間プリベークし
た。The obtained polymer had a weight average molecular weight (M
w) is 8950, and dispersity (Mw / Mn) is 1.8.
Met. Example 6 To the 2-methyladamantyl acrylate polymer prepared in Example 5 above was added 15% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate,
Dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds.
【0147】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を130℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは32mJ/cm2 であり、解像力は0.
30μm L&Sであった。例7 メタクリル酸2−メチルアダマンチルモノマとメタクリ
ル酸3−オキソシクロヘキシルモノマを4:6の割合で
重合容器に仕込み、2モル/Lのトルエン溶液とした。
このトルエン溶液に重合開始剤、AIBNを5モル%の
量で添加し、80℃で約8時間にわたって重合させた。
重合の完結後、メタノールを沈殿剤として精製を行っ
た。次式により表される2−メチルアダマンチルメタク
リレート/3−オキソシクロヘキシルメタクリレート共
重合体が得られた。After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 6 ° C. at 130 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 32 mJ / cm 2 , and the resolving power is 0.
It was 30 μm L & S. Example 7 2-Methyladamantyl methacrylate and 3-oxocyclohexyl methacrylate were charged in a polymerization container at a ratio of 4: 6 to prepare a 2 mol / L toluene solution.
A polymerization initiator, AIBN, was added to this toluene solution in an amount of 5 mol%, and polymerization was carried out at 80 ° C. for about 8 hours.
After completion of the polymerization, methanol was used as a precipitant for purification. A 2-methyladamantyl methacrylate / 3-oxocyclohexyl methacrylate copolymer represented by the following formula was obtained.
【0148】[0148]
【化89】 Embedded image
【0149】得られた共重合体は、組成比(m:n)が
49:51、重量平均分子量(Mw)が14400、そ
して分散度(Mw/Mn)が2.30であった。例8 前記例7において調製した2−メチルアダマンチルメタ
クリレート/3−オキソシクロヘキシルメタクリレート
共重合体に5重量%の酸発生剤、トリフェニルスルホニ
ウムヘキサフルオロアンチモネートを添加し、シクロヘ
キサノンに溶解した。得られたレジスト溶液を、ヘキサ
メチルジシラザン(HMDS)で前処理したシリコン基
板上に膜厚0.7μmでスピンコートし、ホットプレー
ト上で100℃で100秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 49:51, a weight average molecular weight (Mw) of 14400, and a dispersity (Mw / Mn) of 2.30. Example 8 To the 2-methyladamantyl methacrylate / 3-oxocyclohexyl methacrylate copolymer prepared in Example 7 above, 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds.
【0150】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を150℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは9.6mJ/cm2 であり、解像力は
0.275μm L&Sであった。例9 メタクリル酸2−メチルアダマンチルモノマとメタクリ
ル酸3−オキソ−1,1−ジメチルプチルモノマを4:
6の割合で重合容器に仕込み、2モル/Lの1,4−ジ
オキサン溶液とした。このジオキサン溶液に重合開始
剤、AIBNを5モル%の量で添加し、80℃で約8時
間にわたって重合させた。重合の完結後、n−ヘキサン
を沈殿剤として精製を行った。次式により表される2−
メチルアダマンチルメタクリレート/3−オキソ−1,
1−ジメチルブチルメタクリレート共重合体が得られ
た。After completion of the prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 150 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 9.6 mJ / cm 2 , and the resolution was 0.275 μm L & S. Example 9 4-Methyladamantyl Methacrylate Monomer and 3-oxo-1,1-Dimethylputyl Monomer Methacrylate 4:
It was charged into a polymerization vessel at a ratio of 6 to obtain a 2 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to this dioxane solution in an amount of 5 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2 represented by the following formula
Methyl adamantyl methacrylate / 3-oxo-1,
A 1-dimethylbutyl methacrylate copolymer was obtained.
【0151】[0151]
【化90】 Embedded image
【0152】得られた共重合体は、組成比(m:n)が
47:53、重量平均分子量(Mw)が7420、そし
て分散度(Mw/Mn)が2.40であった。例10 前記例9において調製した2−メチルアダマンチルメタ
クリレート/3−オキソ−1,1−ジメチルブチルメタ
クリレート共重合体に5重量%の酸発生剤、トリフェニ
ルスルホニウムヘキサフルオロアンチモネートを添加
し、シクロヘキサノンに溶解した。得られたレジスト溶
液を、ヘキサメチルジシラザン(HMDS)で前処理し
たシリコン基板上に膜厚0.7μmでスピンコートし、
ホットプレート上で100℃で100秒間プリベークし
た。The obtained copolymer had a composition ratio (m: n) of 47:53, a weight average molecular weight (Mw) of 7420 and a dispersity (Mw / Mn) of 2.40. Example 10 To the 2-methyladamantyl methacrylate / 3-oxo-1,1-dimethylbutyl methacrylate copolymer prepared in Example 9 above, 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added to cyclohexanone. Dissolved. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a film thickness of 0.7 μm,
Prebaked at 100 ° C. for 100 seconds on a hot plate.
【0153】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を130℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは32mJ/cm2 であり、解像力は0.
325μm L&Sであった。例11 メタクリル酸2−メチルアダマンチルモノマとメタクリ
ル酸3−メタクリロイルオキシ酪酸メチルモノマを4:
6の割合で重合容器に仕込み、2モル/Lの1,4−ジ
オキサン溶液とした。このジオキサン溶液に重合開始
剤、AIBNを2モル%の量で添加し、80℃で約8時
間にわたって重合させた。重合の完結後、n−ヘキサン
を沈殿剤として精製を行った。次式により表される2−
メチルアダマンチルメタクリレート/3−メタクリロイ
ルオキシ酪酸メチルメタクリレート共重合体が得られ
た。After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 6 ° C. at 130 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 32 mJ / cm 2 , and the resolving power is 0.
325 μm L & S. Example 11 4 -Methyl adamantyl methacrylate and methyl 3-methacryloyloxybutyrate methacrylate 4: 4
It was charged into a polymerization vessel at a ratio of 6 to obtain a 2 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to this dioxane solution in an amount of 2 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2 represented by the following formula
A methyl adamantyl methacrylate / 3-methacryloyloxybutyric acid methyl methacrylate copolymer was obtained.
【0154】[0154]
【化91】 Embedded image
【0155】得られた共重合体は、組成比(m:n)が
50:50、重量平均分子量(Mw)が12090、そ
して分散度(Mw/Mn)が1.95であった。例12 前記例11において調製した2−メチルアダマンチルメ
タクリレート/3−メタクリロイルオキシ酪酸メチルメ
タクリレート共重合体に15重量%の酸発生剤、トリフ
ェニルスルホニウムヘキサフルオロアンチモネートを添
加し、シクロヘキサノンに溶解した。得られたレジスト
溶液を、ヘキサメチルジシラザン(HMDS)で前処理
したシリコン基板上に膜厚0.7μmでスピンコート
し、ホットプレート上で100℃で100秒間プリベー
クした。The obtained copolymer had a composition ratio (m: n) of 50:50, a weight average molecular weight (Mw) of 12090, and a dispersity (Mw / Mn) of 1.95. Example 12 To the 2-methyladamantyl methacrylate / 3-methacryloyloxybutyric acid methyl methacrylate copolymer prepared in Example 11 above, 15% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds.
【0156】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を130℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは29mJ/cm2 であり、解像力は0.
30μm L&Sであった。例13 前記例11に記載の手法を繰り返して、次式により表さ
れかつその組成比(m:n)が55:45、重量平均分
子量(Mw)が11520、そして分散度(Mw/M
n)が2.38の2−メチルアダマンチルメタクリレー
ト/2−ヒドロキシエチルメタクリレート共重合体:After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 6 ° C. at 130 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 29 mJ / cm 2 , and the resolving power is 0.
It was 30 μm L & S. Example 13 The procedure described in Example 11 above was repeated, and the composition ratio (m: n) was represented by the following formula: 55:45, the weight average molecular weight (Mw) was 11520, and the dispersity (Mw / M).
n) 2.38 2-methyladamantyl methacrylate / 2-hydroxyethyl methacrylate copolymer:
【0157】[0157]
【化92】 Embedded image
【0158】を調製した。次いで、上記のようにして調
製した2−メチルアダマンチルメタクリレート/2−ヒ
ドロキシエチルメタクリレート共重合体に15重量%の
酸発生剤、トリフェニルスルホニウムヘキサフルオロア
ンチモネートを添加し、シクロヘキサノンに溶解した。
得られたレジスト溶液を、ヘキサメチルジシラザン(H
MDS)で前処理したシリコン基板上に膜厚0.7μm
でスピンコートし、ホットプレート上で100℃で10
0秒間プリベークした。Was prepared. Next, 15% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added to the 2-methyladamantyl methacrylate / 2-hydroxyethyl methacrylate copolymer prepared as described above and dissolved in cyclohexanone.
The obtained resist solution was treated with hexamethyldisilazane (H
0.7μm film thickness on silicon substrate pre-treated with MDS)
Spin coat at 10 ° C on a hot plate at 100 ° C
Prebaked for 0 seconds.
【0159】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を130℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは12mJ/cm2 であり、解像力は0.
325μm L&Sであった。例14 メタクリル酸2−メチルシクロヘキシルモノマとメタク
リル酸3−オキソシクロヘキシルモノマを4:6の割合
で重合容器に仕込み、2モル/Lのトルエン溶液とし
た。このトルエン溶液に重合開始剤、AIBNを5モル
%の量で添加し、80℃で約8時間にわたって重合させ
た。重合の完結後、メタノールを沈殿剤として精製を行
った。次式により表される2−メチルシクロヘキシルメ
タクリレート/3−オキソシクロヘキシルメタクリレー
ト共重合体が得られた。After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 6 ° C. at 130 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 12 mJ / cm 2 , and the resolving power is 0.
325 μm L & S. Example 14 2-Methylcyclohexyl methacrylate and 3-oxocyclohexyl methacrylate were charged into a polymerization vessel at a ratio of 4: 6 to prepare a 2 mol / L toluene solution. A polymerization initiator, AIBN, was added to this toluene solution in an amount of 5 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, methanol was used as a precipitant for purification. A 2-methylcyclohexyl methacrylate / 3-oxocyclohexyl methacrylate copolymer represented by the following formula was obtained.
【0160】[0160]
【化93】 Embedded image
【0161】得られた共重合体は、組成比(m:n)が
51:49、重量平均分子量(Mw)が7115、そし
て分散度(Mw/Mn)が1.9であった。例15 前記例14において調製した2−メチルシクロヘキシル
メタクリレート/3−オキソシクロヘキシルメタクリレ
ート共重合体に5重量%の酸発生剤、トリフェニルスル
ホニウムヘキサフルオロアンチモネートを添加し、シク
ロヘキサノンに溶解した。得られたレジスト溶液を、ヘ
キサメチルジシラザン(HMDS)で前処理したシリコ
ン基板上に膜厚0.7μmでスピンコートし、ホットプ
レート上で100℃で100秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 51:49, a weight average molecular weight (Mw) of 7115, and a dispersity (Mw / Mn) of 1.9. Example 15 To the 2-methylcyclohexyl methacrylate / 3-oxocyclohexyl methacrylate copolymer prepared in Example 14 above, 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds.
【0162】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を130℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは7.2mJ/cm2 であり、解像力は
0.275μm L&Sであった。例16 前記例7において調製した2−メチルアダマンチルメタ
クリレート/3−オキソシクロヘキシルメタクリレート
共重合体に5重量%の酸発生剤、次式により表される2
−オキソシクロヘキシルメチルシクロヘキシルスルホニ
ウムトリクロロスルホネート:After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 6 ° C. at 130 ° C.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 7.2 mJ / cm 2 , and the resolution was 0.275 μm L & S. Example 16 2-Methyladamantylmethacrylate / 3-oxocyclohexylmethacrylate copolymer prepared in Example 7 above with 5% by weight of acid generator, represented by the formula 2
-Oxocyclohexylmethylcyclohexylsulfonium trichlorosulfonate:
【0163】[0163]
【化94】 Embedded image
【0164】を添加し、シクロヘキサノンに溶解した。
得られたレジスト溶液を、ヘキサメチルジシラザン(H
MDS)で前処理したシリコン基板上に膜厚0.7μm
でスピンコートし、ホットプレート上で100℃で10
0秒間プリベークした。プリベークの完了後、得られた
レジスト膜をArF露光装置(ニコン社製、NA=0.
55)で波長193nmのArFレーザ光のパターンに選
択露光した。続いて、露光後のレジスト膜を130℃で
60秒間PEB(露光後ベーク)した。その後、レジス
ト膜を0.27Nのテトラメチルアンモニウムハイドロ
キシド(TMAH)水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは6mJ/cm2 であり、解像力は0.
20μm L&Sであった。例17 次式により表される2−メチルアダマンチルメタクリレ
ート/p−ビニルフェノール(組成比=23:77、重
量平均分子量(Mw)=6480、分散度=3.1):Was added and dissolved in cyclohexanone.
The obtained resist solution was treated with hexamethyldisilazane (H
0.7μm film thickness on silicon substrate pre-treated with MDS)
Spin coat at 10 ° C on a hot plate at 100 ° C
Prebaked for 0 seconds. After the completion of prebaking, the obtained resist film was exposed to an ArF exposure device (manufactured by Nikon Corporation, NA = 0.
At 55), selective exposure was performed to an ArF laser beam pattern having a wavelength of 193 nm. Subsequently, the resist film after exposure was PEB (post-exposure bake) at 130 ° C. for 60 seconds. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 6 mJ / cm 2 , and the resolving power is 0.
It was 20 μm L & S. Example 17 2-Methyladamantyl methacrylate / p-vinylphenol represented by the following formula (composition ratio = 23: 77, weight average molecular weight (Mw) = 6480, dispersity = 3.1):
【0165】[0165]
【化95】 Embedded image
【0166】に2重量%の酸発生剤、トリフェニルスル
ホニウムヘキサフルオロアンチモネートを添加し、シク
ロヘキサノンに溶解した。得られたレジスト溶液を、ヘ
キサメチルジシラザン(HMDS)で前処理したシリコ
ン基板上に膜厚0.7μmでスピンコートし、ホットプ
レート上で100℃で100秒間プリベークした。プリ
ベークの完了後、得られたレジスト膜をKrFエキシマ
ステッパ(ニコン社製、NA=0.45)で波長248
nmのKrFレーザ光のパターンに選択露光した。続い
て、露光後のレジスト膜を130℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.27
Nのテトラメチルアンモニウムハイドロキシド(TMA
H)水溶液で60秒間現像し、さらに純水で30秒間リ
ンスした。露光に用いたレーザ光パターンに相当する所
望のレジストパターンがパターンの剥れを生じることな
く得られた。なお、本例での照射線量の闘値エネルギE
thは82mJ/cm2 であり、解像力は0.325μm
L&Sであった。例18 前記例5において調製した2−メチルアダマンチルアク
リレート重合体、重量平均分子量(Mw)=8950及
び分散度=1.8、を次式により表されるポリビニルフ
ェノール、重量平均分子量(Mw)=5150及び分散
度=2.8:2% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added to and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds. After completion of the pre-baking, the obtained resist film was irradiated with a KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.45) at a wavelength of 248.
The pattern was selectively exposed to a pattern of a KrF laser beam of nm. Next, the exposed resist film is PEB at 130 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.27
N tetramethylammonium hydroxide (TMA
H) The solution was developed for 60 seconds with an aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy E of the irradiation dose in this example
th is 82 mJ / cm 2 , and resolution is 0.325 μm.
It was L & S. Example 18 Polyvinylphenol represented by the following formula, wherein the 2-methyladamantyl acrylate polymer prepared in the above Example 5, weight average molecular weight (Mw) = 8950 and dispersity = 1.8, weight average molecular weight (Mw) = 5150 And dispersity = 2.8:
【0167】[0167]
【化96】 [Chemical 96]
【0168】に20重量%の割合で添加し、さらに5重
量%の酸発生剤、トリフェニルスルホニウムヘキサフル
オロアンチモネートを添加し、得られた混合物をシクロ
ヘキサノンに溶解した。得られたレジスト溶液を、ヘキ
サメチルジシラザン(HMDS)で前処理したシリコン
基板上に膜厚0.7μmでスピンコートし、ホットプレ
ート上で100℃で100秒間プリベークした。20% by weight was added to the above, and further 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate, was added, and the resulting mixture was dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds.
【0169】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を110℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは8.9mJ/cm2 であり、解像力は
0.325μm L&Sであった。例19 前記例18で用いたものと同じポリビニルフェノール、
重量平均分子量(Mw)=5150及び分散度=2.
8、に次式により表される1−アダマンチルカルボン酸
2−メチルアダマンチルエステル:After completion of the prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 110 ° C. for 6 minutes.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 8.9 mJ / cm 2 , and the resolution was 0.325 μm L & S. Example 19 The same polyvinylphenol used in Example 18 above,
Weight average molecular weight (Mw) = 5150 and dispersity = 2.
1-adamantylcarboxylic acid 2-methyladamantyl ester represented by the following formula:
【0170】[0170]
【化97】 Embedded image
【0171】を30重量%の割合で添加し、さらに5重
量%の酸発生剤、トリフェニルスルホニウムヘキサフル
オロアンチモネートを添加し、得られた混合物をシクロ
ヘキサノンに溶解した。得られたレジスト溶液を、ヘキ
サメチルジシラザン(HMDS)で前処理したシリコン
基板上に膜厚0.7μmでスピンコートし、ホットプレ
ート上で100℃で100秒間プリベークした。Was added at a rate of 30% by weight, and further 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate was added, and the resulting mixture was dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS) to a thickness of 0.7 μm, and prebaked on a hot plate at 100 ° C. for 100 seconds.
【0172】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(ニコン社製、NA=0.4
5)で波長248nmのKrFレーザ光のパターンに選択
露光した。続いて、露光後のレジスト膜を110℃で6
0秒間PEB(露光後ベーク)した。その後、レジスト
膜を0.27Nのテトラメチルアンモニウムハイドロキ
シド(TMAH)水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは11mJ/cm2 であり、解像力は0.
35μm L&Sであった。例20 次式により表されかつその組成比(m:n)が5:5、
そして重量平均分子量(Mw)が23000である共重
合体を用意した。After the completion of prebaking, the obtained resist film was changed to KrF excimer stepper (manufactured by Nikon Corporation, NA = 0.4).
In step 5), a pattern of KrF laser light having a wavelength of 248 nm was selectively exposed. Then, the resist film after exposure is exposed to 110 ° C. for 6 minutes.
PEB (bake after exposure) was performed for 0 second. Then, the resist film was developed with a 0.27N tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 11 mJ / cm 2 , and the resolving power is 0.
It was 35 μm L & S. Example 20 Represented by the following formula and having a composition ratio (m: n) of 5: 5,
Then, a copolymer having a weight average molecular weight (Mw) of 23000 was prepared.
【0173】[0173]
【化98】 Embedded image
【0174】この共重合体に共重合体の2重量%の酸発
生剤、トリフェニルスルホニウムトリフレート(TPS
SO3 CF3 )を添加し、共重合体濃度が15重量%と
なるように乳酸エチル(EL)に溶解した。得られたレ
ジスト溶液を、ヘキサメチルジシラザン(HMDS)で
前処理したシリコン基板上にスピンコートし、ホットプ
レート上で100℃で1分間プリベークした。膜厚1.
0μmのレジスト膜が得られた。2% by weight of the copolymer, triphenylsulfonium triflate (TPS), was added to this copolymer.
SO 3 CF 3 ) was added and dissolved in ethyl lactate (EL) so that the copolymer concentration was 15% by weight. The obtained resist solution was spin-coated on a silicon substrate pretreated with hexamethyldisilazane (HMDS), and prebaked on a hot plate at 100 ° C. for 1 minute. Film thickness 1.
A resist film of 0 μm was obtained.
【0175】プリベークの完了後、得られたレジスト膜
をArFエキシマレーザコンタクトアライナ(NA=
0.55)で波長193nmのArFレーザ光のパターン
に選択露光した。続いて、露光直後のレジスト膜を15
0℃のホットプレート上で60秒間PEB(露光後ベー
ク)した。その後、レジスト膜を東京応化工業社製のア
ルカリ現像液、MMD−3で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたマスクサイズ通
りのレジストパターンがパターンのクラックや剥れを生
じることなく得られた。解像力は0.50μm L&S
(ライン・アンド・スペース)であった。例21 (比較例) 前記例20に記載の手法を繰り返した。但し、本例で
は、比較のため、次式により表されかつその組成比
(m:n)が5:5、そして重量平均分子量(Mw)が
14000である共重合体を用意した。After completion of the prebaking, the obtained resist film is formed into an ArF excimer laser contact aligner (NA = NA).
0.55) was selectively exposed to a pattern of ArF laser light having a wavelength of 193 nm. Then, the resist film immediately after the exposure is
PEB (post-exposure bake) for 60 seconds on a 0 ° C. hot plate. After that, the resist film was developed for 60 seconds with MMD-3, an alkaline developer manufactured by Tokyo Ohka Kogyo Co., Ltd., and rinsed with pure water for 30 seconds. A resist pattern according to the mask size used for exposure was obtained without causing cracking or peeling of the pattern. Resolution is 0.50 μm L & S
(Line and space). Example 21 (Comparative Example) The procedure described in Example 20 was repeated. However, in this example, for comparison, a copolymer represented by the following formula, having a composition ratio (m: n) of 5: 5 and a weight average molecular weight (Mw) of 14,000 was prepared.
【0176】[0176]
【化99】 Embedded image
【0177】0.50μm L&S(ライン・アンド・
スペース)の解像力でレジストパターンが得られたけれ
ども、パターン周辺にクラックを生じてしまった。例22 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が18000である
共重合体を用意した。0.50 μm L & S (line and
Although a resist pattern was obtained with the resolution of (space), cracks were generated around the pattern. Example 22 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 18,000 was prepared.
【0178】[0178]
【化100】 [Chemical 100]
【0179】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例23 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が11000である
共重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without causing pattern cracking or peeling. The resolution was 0.50 μm L & S (line and space). Example 23 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 11,000 was prepared.
【0180】[0180]
【化101】 Embedded image
【0181】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例24 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が8000である共
重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without causing pattern cracking or peeling. The resolution was 0.50 μm L & S (line and space). Example 24 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 8000 was prepared.
【0182】[0182]
【化102】 Embedded image
【0183】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例25 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が9000である共
重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.50 μm L & S (line and space). Example 25 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 9000 was prepared.
【0184】[0184]
【化103】 Embedded image
【0185】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例26 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が7800である共
重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.50 μm L & S (line and space). Example 26 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 7800 was prepared.
【0186】[0186]
【化104】 [Chemical 104]
【0187】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例27 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が6500である共
重合体を用意した。A resist pattern according to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.50 μm L & S (line and space). Example 27 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 6500 was prepared.
【0188】[0188]
【化105】 Embedded image
【0189】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例28 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が16000である
共重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without cracking or peeling of the pattern. The resolution was 0.50 μm L & S (line and space). Example 28 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 16000 was prepared.
【0190】[0190]
【化106】 [Chemical formula 106]
【0191】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.60μm L&S(ライン・ア
ンド・スペース)であった。例29 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が12500である
共重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.60 μm L & S (line and space). Example 29 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 12,500 was prepared.
【0192】[0192]
【化107】 [Chemical formula 107]
【0193】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例30 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が18000である
共重合体を用意し、また、露光源として、ArFエキシ
マレーザコンタクトアライナに代えて、遠紫外線光コン
タクトアライナを使用した。A resist pattern according to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.50 μm L & S (line and space). Example 30 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 18000 was prepared, and a far ultraviolet light contact aligner was used as an exposure source instead of the ArF excimer laser contact aligner.
【0194】[0194]
【化108】 Embedded image
【0195】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.50μm L&S(ライン・ア
ンド・スペース)であった。例31 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が17500である
共重合体を用意し、また、露光源として、ArFエキシ
マレーザコンタクトアライナに代えて、遠紫外線光コン
タクトアライナを使用した。A resist pattern corresponding to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.50 μm L & S (line and space). Example 31 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 17500 was prepared, and a far-ultraviolet light contact aligner was used as an exposure source instead of the ArF excimer laser contact aligner.
【0196】[0196]
【化109】 [Chemical 109]
【0197】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.55μm L&S(ライン・ア
ンド・スペース)であった。例32 前記例20に記載の手法を繰り返した。但し、本例で
は、次式により表されかつその組成比(m:n)が5:
5、そして重量平均分子量(Mw)が9500である共
重合体を用意した。A resist pattern corresponding to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.55 μm L & S (line and space). Example 32 The procedure described in Example 20 above was repeated. However, in this example, the composition ratio (m: n) represented by the following equation is 5:
5, and a copolymer having a weight average molecular weight (Mw) of 9500 was prepared.
【0198】[0198]
【化110】 Embedded image
【0199】露光に用いたマスクサイズ通りのレジスト
パターンがパターンのクラックや剥れを生じることなく
得られた。解像力は0.60μm L&S(ライン・ア
ンド・スペース)であった。例33 メタクリル酸2−メチル−2−アダマンチルモノマとメ
タクリル酸モノマを7:3の割合で重合容器に仕込み、
1モル/Lの1,4−ジオキサン溶液とした。この1,
4−ジオキサン溶液に重合開始剤、AIBN(アゾイソ
ブチロニトリル)を20モル%の量で添加し、80℃で
約8時間にわたって重合させた。重合の完結後、n−ヘ
キサンを沈殿剤として精製を行った。次式により表され
るメタクリル酸2−メチル−2−アダマンチル/メタク
リル酸共重合体が得られた。A resist pattern corresponding to the mask size used for exposure was obtained without causing cracks or peeling of the pattern. The resolution was 0.60 μm L & S (line and space). Example 33 2-Methyl-2-adamantyl methacrylate monomer and methacrylate monomer were charged in a polymerization container at a ratio of 7: 3,
A 1 mol / L 1,4-dioxane solution was prepared. This one
A polymerization initiator, AIBN (azoisobutyronitrile), was added to the 4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / methacrylic acid copolymer represented by the following formula was obtained.
【0200】[0200]
【化111】 [Chemical 111]
【0201】得られた共重合体は、組成比(m:n)が
7:3、重量平均分子量(Mw)が8500、そして分
散度(Mw/Mn)が2.10であった。例34 前記例33において調製したメタクリル酸2−メチル−
2−アダマンチル/メタクリル酸共重合体に2重量%の
酸発生剤、トリフェニルスルホニウムトリフレート(T
PSSO3 CF3 )を添加し、プロピレングリコールモ
ノメチルエーテルアセテート(PGMEA)に溶解し
た。得られたレジスト溶液を、ヘキサメチルジシラザン
(HMDS)で前処理したシリコン基板上に膜厚0.4
μmでスピンコートし、ホットプレート上で120℃で
60秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 7: 3, a weight average molecular weight (Mw) of 8500, and a dispersity (Mw / Mn) of 2.10. Example 34 2-Methyl methacrylate prepared in Example 33 above
2-adamantyl / methacrylic acid copolymer with 2% by weight of an acid generator, triphenylsulfonium triflate (T
PSSO 3 CF 3 ) was added and dissolved in propylene glycol monomethyl ether acetate (PGMEA). The obtained resist solution was applied to a silicon substrate pretreated with hexamethyldisilazane (HMDS) to give a film thickness of 0.4.
It was spin coated with a thickness of μm and prebaked on a hot plate at 120 ° C. for 60 seconds.
【0202】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のテトラメチルアンモニウムハイドロキシド
(TMAH)水溶液で60秒間現像し、さらに純水で3
0秒間リンスした。露光に用いたレーザ光パターンに相
当する所望のレジストパターンがパターンの剥れを生じ
ることなく得られた。なお、本例での照射線量の闘値エ
ネルギEthは21.5mJ/cm2 であり、解像力は0.
175μm L&S(ライン・アンド・スペース)であ
った。例35 前記例34に記載の手法を繰り返した。但し、本例で
は、露光装置として、ArFエキシマ露光装置に代えて
KrFエキシマステッパ(NA=0.45)を使用し、
波長248nmのKrFレーザ光で選択露光を行った。露
光に用いたレーザ光パターンに相当する所望のレジスト
パターンがパターンの剥れを生じることなく得られた。
なお、本例での照射線量の闘値エネルギEthは1.4
8mJ/cm2であり、解像力は0.275μm L&S
(ライン・アンド・スペース)であった。例36 メタクリル酸2−メチル−2−アダマンチルモノマ、メ
タクリル酸t−ブチルモノマ及びメタクリル酸モノマを
8:7:5の割合で重合容器に仕込み、1モル/Lの
1,4−ジオキサン溶液とした。この1,4−ジオキサ
ン溶液に重合開始剤、AIBNを20モル%の量で添加
し、80℃で約8時間にわたって重合させた。重合の完
結後、n−ヘキサンを沈殿剤として精製を行った。次式
により表されるメタクリル酸2−メチル−2−アダマン
チル/メタクリル酸t−ブチル/メタクリル酸共重合体
が得られた。After the completion of prebaking, the obtained resist film was irradiated with an ArF excimer exposure device (NA = 0.55) at a wavelength of 1.
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
Develop with an 8 wt% tetramethylammonium hydroxide (TMAH) aqueous solution for 60 seconds, and further deionize with pure water.
Rinse for 0 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 21.5 mJ / cm 2 , and the resolution is 0.
It was 175 μm L & S (line and space). Example 35 The procedure described in Example 34 above was repeated. However, in this example, as the exposure apparatus, a KrF excimer stepper (NA = 0.45) is used instead of the ArF excimer exposure apparatus,
Selective exposure was performed with a KrF laser beam having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern.
The threshold energy Eth of the irradiation dose in this example is 1.4.
8 mJ / cm 2 with a resolution of 0.275 μm L & S
(Line and space). Example 36 2-Methyl-2-adamantyl methacrylate monomer, t-butyl methacrylate methacrylate and methacrylic acid monomer were charged in a polymerization container at a ratio of 8: 7: 5 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / t-butyl methacrylate / methacrylic acid copolymer represented by the following formula was obtained.
【0203】[0203]
【化112】 [Chemical 112]
【0204】得られた共重合体は、組成比(l:m:
n)が50:29:21、重量平均分子量(Mw)が7
800、そして分散度(Mw/Mn)が2.20であっ
た。例37 前記例36において調製したメタクリル酸2−メチル−
2−アダマンチル/メタクリル酸t−ブチル/メタクリ
ル酸共重合体に2重量%の酸発生剤、トリフェニルスル
ホニウムトリフレート(TPSSO3 CF3 )を添加
し、プロピレングリコールモノメチルエーテルアセテー
ト(PGMEA)に溶解した。得られたレジスト溶液
を、HMDSで前処理したシリコン基板上に膜厚0.4
μmでスピンコートし、ホットプレート上で120℃で
60秒間プリベークした。The obtained copolymer had a composition ratio (l: m:
n) is 50:29:21 and the weight average molecular weight (Mw) is 7
800, and the dispersity (Mw / Mn) was 2.20. Example 37 2-Methyl methacrylate prepared in Example 36 above
To a 2-adamantyl / t-butyl methacrylate / methacrylic acid copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added and dissolved in propylene glycol monomethyl ether acetate (PGMEA). . The obtained resist solution was applied to a silicon substrate pretreated with HMDS to give a film thickness of 0.4.
It was spin coated with a thickness of μm and prebaked on a hot plate at 120 ° C. for 60 seconds.
【0205】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは1.4mJ/cm2 であり、解像力は
0.170μmL&S(ライン・アンド・スペース)で
あった。例38 前記例37に記載の手法を繰り返した。但し、本例で
は、露光装置として、ArFエキシマ露光装置に代えて
KrFエキシマステッパ(NA=0.45)を使用し、
波長248nmのKrFレーザ光で選択露光を行った。露
光に用いたレーザ光パターンに相当する所望のレジスト
パターンがパターンの剥れを生じることなく得られた。
なお、本例での照射線量の闘値エネルギEthは14.
4mJ/cm2であり、解像力は0.250μm L&S
(ライン・アンド・スペース)であった。例39 メタクリル酸2−メチル−2−アダマンチルモノマ及び
イタコン酸モノマを9:1の割合で重合容器に仕込み、
1モル/Lの1,4−ジオキサン溶液とした。この1,
4−ジオキサン溶液に重合開始剤、AIBNを20モル
%の量で添加し、80℃で約8時間にわたって重合させ
た。重合の完結後、n−ヘキサンを沈殿剤として精製を
行った。次式により表されるメタクリル酸2−メチル−
2−アダマンチル/イタコン酸共重合体が得られた。After the completion of prebaking, the obtained resist film was irradiated with an ArF excimer exposure device (NA = 0.55) at a wavelength of 1.
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
It was developed for 60 seconds with an 8 wt% TMAH aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 1.4 mJ / cm 2 , and the resolution was 0.170 μmL & S (line and space). Example 38 The procedure described in Example 37 above was repeated. However, in this example, as the exposure apparatus, a KrF excimer stepper (NA = 0.45) is used instead of the ArF excimer exposure apparatus,
Selective exposure was performed with a KrF laser beam having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern.
The threshold energy Eth of the irradiation dose in this example is 14.
4 mJ / cm 2 and resolution is 0.250 μm L & S
(Line and space). Example 39 2-Methyl-2-adamantyl methacrylate monomer and itaconic acid monomer were charged to a polymerization vessel at a ratio of 9: 1.
A 1 mol / L 1,4-dioxane solution was prepared. This one
A polymerization initiator, AIBN, was added to the 4-dioxane solution in an amount of 20 mol%, and polymerization was performed at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methylmethacrylate represented by the following formula
A 2-adamantyl / itaconic acid copolymer was obtained.
【0206】[0206]
【化113】 [Chemical 113]
【0207】得られた共重合体は、組成比(m:n)が
88:12、重量平均分子量(Mw)が6700、そし
て分散度(Mw/Mn)が2.18であった。例40 前記例39において調製したメタクリル酸2−メチル−
2−アダマンチル/イタコン酸共重合体に2重量%の酸
発生剤、トリフェニルスルホニウムトリフレート(TP
SSO3 CF3 )を添加し、乳酸エチル(EL)に溶解
した。得られたレジスト溶液を、HMDSで前処理した
シリコン基板上に膜厚0.4μmでスピンコートし、ホ
ットプレート上で120℃で60秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 88:12, a weight average molecular weight (Mw) of 6,700 and a dispersity (Mw / Mn) of 2.18. Example 40 2-Methyl methacrylate prepared in Example 39 above
2-adamantyl / itaconic acid copolymer with 2% by weight of acid generator, triphenylsulfonium triflate (TP
SSO 3 CF 3 ) was added and dissolved in ethyl lactate (EL). The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0208】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは2.8mJ/cm2 であり、解像力は
0.175μmL&S(ライン・アンド・スペース)で
あった。例41 前記例40に記載の手法を繰り返した。但し、本例で
は、露光装置として、ArFエキシマ露光装置に代えて
KrFエキシマステッパ(NA=0.45)を使用し、
波長248nmのKrFレーザ光で選択露光を行った。露
光に用いたレーザ光パターンに相当する所望のレジスト
パターンがパターンの剥れを生じることなく得られた。
なお、本例での照射線量の闘値エネルギEthは25.
0mJ/cm2であり、解像力は0.275μm L&S
(ライン・アンド・スペース)であった。例42 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ビニルベンゼンスルホン酸モノマを8:2の割合で重合
容器に仕込み、1モル/Lの1,4−ジオキサン溶液と
した。この1,4−ジオキサン溶液に重合開始剤、AI
BNを20モル%の量で添加し、80℃で約8時間にわ
たって重合させた。重合の完結後、n−ヘキサンを沈殿
剤として精製を行った。次式により表されるメタクリル
酸2−メチル−2−アダマンチル/ビニルベンゼンスル
ホン酸共重合体が得られた。After the completion of prebaking, the obtained resist film was irradiated with an ArF excimer exposure device (NA = 0.55) at a wavelength of 1.
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
It was developed for 60 seconds with an 8 wt% TMAH aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 2.8 mJ / cm 2 , and the resolution was 0.175 μmL & S (line and space). Example 41 The procedure described in Example 40 above was repeated. However, in this example, as the exposure apparatus, a KrF excimer stepper (NA = 0.45) is used instead of the ArF excimer exposure apparatus,
Selective exposure was performed with a KrF laser beam having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern.
The threshold energy Eth of the irradiation dose in this example is 25.
0 mJ / cm 2 with a resolution of 0.275 μm L & S
(Line and space). Example 42 2-Methyl-2-adamantyl methacrylate monomer and vinylbenzenesulfonic acid monomer were charged into a polymerization vessel at a ratio of 8: 2 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AI, is added to the 1,4-dioxane solution.
BN was added in an amount of 20 mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / vinylbenzenesulfonic acid copolymer represented by the following formula was obtained.
【0209】[0209]
【化114】 [Chemical 114]
【0210】得られた共重合体は、組成比(m:n)が
76:24、重量平均分子量(Mw)が6400、そし
て分散度(Mw/Mn)が2.42であった。例43 前記例42において調製したメタクリル酸2−メチル−
2−アダマンチル/ビニルベンゼンスルホン酸共重合体
に2重量%の酸発生剤、トリフェニルスルホニウムトリ
フレート(TPSSO3 CF3 )を添加し、乳酸エチル
(EL)に溶解した。得られたレジスト溶液を、HMD
Sで前処理したシリコン基板上に膜厚0.4μmでスピ
ンコートし、ホットプレート上で120℃で60秒間プ
リベークした。The obtained copolymer had a composition ratio (m: n) of 76:24, a weight average molecular weight (Mw) of 6,400, and a dispersity (Mw / Mn) of 2.42. Example 43 2-Methyl methacrylate prepared in Example 42 above
2-adamantyl / vinyl benzenesulfonic acid copolymer 2 wt% of the acid generator, was added triphenylsulfonium triflate (TPSSO 3 CF 3), was dissolved in ethyl lactate (EL). The obtained resist solution is used for HMD
A silicon substrate pretreated with S was spin-coated with a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0211】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.23
6重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは12.4mJ/cm2 であり、解像力
は0.250μm L&S(ライン・アンド・スペー
ス)であった。例44 メタクリル酸2−メチル−2−アダマンチルモノマ及び
メタクリル酸アミドモノマを7:3の割合で重合容器に
仕込み、1モル/Lの1,4−ジオキサン溶液とした。
この1,4−ジオキサン溶液に重合開始剤、AIBNを
20モル%の量で添加し、80℃で約8時間にわたって
重合させた。重合の完結後、n−ヘキサンを沈殿剤とし
て精製を行った。次式により表されるメタクリル酸2−
メチル−2−アダマンチル/メタクリル酸アミド共重合
体が得られた。After completion of the prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.23
It was developed with a 6% by weight TMAH aqueous solution for 60 seconds and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 12.4 mJ / cm 2 , and the resolution was 0.250 μm L & S (line and space). Example 44 2-Methyl-2-adamantyl methacrylate monomer and methacrylic acid amide monomer were charged in a polymerization container at a ratio of 7: 3 to prepare a 1 mol / L 1,4-dioxane solution.
A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methacrylic acid represented by the following formula
A methyl-2-adamantyl / methacrylic acid amide copolymer was obtained.
【0212】[0212]
【化115】 [Chemical 115]
【0213】得られた共重合体は、組成比(m:n)が
75:25、重量平均分子量(Mw)が7600、そし
て分散度(Mw/Mn)が2.13であった。例45 前記例44において調製したメタクリル酸2−メチル−
2−アダマンチル/メタクリル酸アミド共重合体に2重
量%の酸発生剤、トリフェニルスルホニウムトリフレー
ト(TPSSO3 CF3 )を添加し、乳酸エチル(E
L)に溶解した。得られたレジスト溶液を、HMDSで
前処理したシリコン基板上に膜厚0.4μmでスピンコ
ートし、ホットプレート上で120℃で60秒間プリベ
ークした。The obtained copolymer had a composition ratio (m: n) of 75:25, a weight average molecular weight (Mw) of 7,600 and a dispersity (Mw / Mn) of 2.13. Example 45 2-Methyl methacrylate prepared in Example 44 above
To the 2-adamantyl / methacrylic acid amide copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added, and ethyl lactate (E
L). The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0214】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.23
6重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは24.0mJ/cm2 であり、解像力
は0.275μm L&S(ライン・アンド・スペー
ス)であった。例46 メタクリル酸2−メチル−2−アダマンチルモノマ及び
マレイミドモノマを7:3の割合で重合容器に仕込み、
1モル/Lの1,4−ジオキサン溶液とした。この1,
4−ジオキサン溶液に重合開始剤、AIBNを20モル
%の量で添加し、80℃で約8時間にわたって重合させ
た。重合の完結後、n−ヘキサンを沈殿剤として精製を
行った。次式により表されるメタクリル酸2−メチル−
2−アダマンチル/マレイミド共重合体が得られた。After completion of the prebaking, the obtained resist film was subjected to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.23
It was developed with a 6% by weight TMAH aqueous solution for 60 seconds and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 24.0 mJ / cm 2 , and the resolution was 0.275 μm L & S (line and space). Example 46 2-Methyl-2-adamantyl methacrylate monomer and maleimide monomer were charged in a polymerization container at a ratio of 7: 3,
A 1 mol / L 1,4-dioxane solution was prepared. This one
A polymerization initiator, AIBN, was added to the 4-dioxane solution in an amount of 20 mol%, and polymerization was performed at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methylmethacrylate represented by the following formula
A 2-adamantyl / maleimide copolymer was obtained.
【0215】[0215]
【化116】 Embedded image
【0216】得られた共重合体は、組成比(m:n)が
71:29、重量平均分子量(Mw)が8200、そし
て分散度(Mw/Mn)が2.55であった。例47 前記例46において調製したメタクリル酸2−メチル−
2−アダマンチル/マレイミド共重合体に2重量%の酸
発生剤、トリフェニルスルホニウムトリフレート(TP
SSO3 CF3 )を添加し、乳酸エチル(EL)に溶解
した。得られたレジスト溶液を、HMDSで前処理した
シリコン基板上に膜厚0.4μmでスピンコートし、ホ
ットプレート上で120℃で60秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 71:29, a weight average molecular weight (Mw) of 8200, and a dispersity (Mw / Mn) of 2.55. Example 47 2-Methyl methacrylate prepared in Example 46 above
2-adamantyl / maleimide copolymer with 2% by weight of acid generator, triphenylsulfonium triflate (TP
SSO 3 CF 3 ) was added and dissolved in ethyl lactate (EL). The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0217】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.23
6重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは30.0mJ/cm2 であり、解像力
は0.275μm L&S(ライン・アンド・スペー
ス)であった。例48 メタクリル酸2−メチル−2−アダマンチルモノマ及び
無水イタコン酸モノマを8:2の割合で重合容器に仕込
み、1モル/Lの1,4−ジオキサン溶液とした。この
1,4−ジオキサン溶液に重合開始剤、AIBNを20
モル%の量で添加し、80℃で約8時間にわたって重合
させた。重合の完結後、n−ヘキサンを沈殿剤として精
製を行った。次式により表されるメタクリル酸2−メチ
ル−2−アダマンチル/無水イタコン酸共重合体が得ら
れた。After the completion of prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.23
It was developed with a 6% by weight TMAH aqueous solution for 60 seconds and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 30.0 mJ / cm 2 , and the resolving power was 0.275 μm L & S (line and space). Example 48 2-Methyl-2-adamantyl methacrylate monomer and itaconic anhydride monomer were charged into a polymerization vessel at a ratio of 8: 2 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, is added to the 1,4-dioxane solution in an amount of 20
It was added in an amount of mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / itaconic anhydride copolymer represented by the following formula was obtained.
【0218】[0218]
【化117】 [Chemical 117]
【0219】得られた共重合体は、組成比(m:n)が
72:28、重量平均分子量(Mw)が8700、そし
て分散度(Mw/Mn)が2.31であった。例49 前記例48において調製したメタクリル酸2−メチル−
2−アダマンチル/無水イタコン酸共重合体に2重量%
の酸発生剤、トリフェニルスルホニウムトリフレート
(TPSSO3 CF3 )を添加し、乳酸エチル(EL)
に溶解した。得られたレジスト溶液を、HMDSで前処
理したシリコン基板上に膜厚0.4μmでスピンコート
し、ホットプレート上で120℃で60秒間プリベーク
した。The obtained copolymer had a composition ratio (m: n) of 72:28, a weight average molecular weight (Mw) of 8700, and a dispersity (Mw / Mn) of 2.31. Example 49 2-Methyl methacrylate prepared in Example 48 above
2% by weight to 2-adamantyl / itaconic anhydride copolymer
Acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added, and ethyl lactate (EL) was added.
Was dissolved. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0220】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは26.1mJ/cm2 であり、解像力
は0.275μm L&S(ライン・アンド・スペー
ス)であった。例50 メタクリル酸2−メチル−2−アダマンチルモノマ及び
α−アクリル酸−(R)−(+)−β,β−ジメチル−
γ−ブチロラクトンモノマを7:3の割合で重合容器に
仕込み、1モル/Lの1,4−ジオキサン溶液とした。
この1,4−ジオキサン溶液に重合開始剤、AIBNを
20モル%の量で添加し、80℃で約8時間にわたって
重合させた。重合の完結後、n−ヘキサンを沈殿剤とし
て精製を行った。次式により表されるメタクリル酸2−
メチル−2−アダマンチル/α−アクリル酸−(R)−
(+)−β,β−ジメチル−γ−ブチロラクトン共重合
体が得られた。After the completion of prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
It was developed for 60 seconds with an 8 wt% TMAH aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 26.1 mJ / cm 2 , and the resolution was 0.275 μm L & S (line and space). Example 50 2-Methyl-2-adamantyl methacrylate and α-acrylic acid- (R)-(+)-β, β-dimethyl-
The γ-butyrolactone monomer was charged into the polymerization vessel at a ratio of 7: 3 to prepare a 1 mol / L 1,4-dioxane solution.
A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methacrylic acid represented by the following formula
Methyl-2-adamantyl / α-acrylic acid- (R)-
A (+)-β, β-dimethyl-γ-butyrolactone copolymer was obtained.
【0221】[0221]
【化118】 Embedded image
【0222】得られた共重合体は、組成比(m:n)が
74:26、重量平均分子量(Mw)が6200、そし
て分散度(Mw/Mn)が2.25であった。例51 前記例50において調製したメタクリル酸2−メチル−
2−アダマンチル/α−アクリル酸−(R)−(+)−
β,β−ジメチル−γ−ブチロラクトン共重合体に2重
量%の酸発生剤、トリフェニルスルホニウムトリフレー
ト(TPSSO 3 CF3 )を添加し、乳酸エチル(E
L)に溶解した。得られたレジスト溶液を、HMDSで
前処理したシリコン基板上に膜厚0.4μmでスピンコ
ートし、ホットプレート上で120℃で60秒間プリベ
ークした。The composition ratio (m: n) of the obtained copolymer was
74:26, weight average molecular weight (Mw) 6200,
And the dispersity (Mw / Mn) was 2.25.Example 51 2-Methyl methacrylate prepared in Example 50 above
2-adamantyl / α-acrylic acid- (R)-(+)-
Double in β, β-dimethyl-γ-butyrolactone copolymer
% Acid generator, triphenylsulfonium triflate
To (TPSSO ThreeCFThree) Is added, and ethyl lactate (E
L). The obtained resist solution is subjected to HMDS
Spin film with a thickness of 0.4 μm on a pretreated silicon substrate.
And place the plate on a hot plate for 60 seconds at 120 ° C.
I went to
【0223】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは1.9mJ/cm2 であり、解像力は
0.170μmL&S(ライン・アンド・スペース)で
あった。例52 前記例51に記載の手法を繰り返した。但し、本例で
は、露光装置として、ArFエキシマ露光装置に代えて
KrFエキシマステッパ(NA=0.45)を使用し、
波長248nmのKrFレーザ光で選択露光を行った。露
光に用いたレーザ光パターンに相当する所望のレジスト
パターンがパターンの剥れを生じることなく得られた。
なお、本例での照射線量の闘値エネルギEthは15.
0mJ/cm2であり、解像力は0.250μm L&S
(ライン・アンド・スペース)であった。例53 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ビニルヒドロキシルオキシムモノマを4:6の割合で重
合容器に仕込み、1モル/Lの1,4−ジオキサン溶液
とした。この1,4−ジオキサン溶液に重合開始剤、A
IBNを20モル%の量で添加し、80℃で約8時間に
わたって重合させた。重合の完結後、n−ヘキサンを沈
殿剤として精製を行った。次式により表されるメタクリ
ル酸2−メチル−2−アダマンチル/ビニルヒドロキシ
ルオキシム共重合体が得られた。After the completion of prebaking, the obtained resist film was irradiated with an ArF excimer exposure device (NA = 0.55) at a wavelength of 1.
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 1.9 mJ / cm 2 , and the resolution was 0.170 μmL & S (line and space). Example 52 The procedure described in Example 51 above was repeated. However, in this example, as the exposure apparatus, a KrF excimer stepper (NA = 0.45) is used instead of the ArF excimer exposure apparatus,
Selective exposure was performed with a KrF laser beam having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern.
The threshold energy Eth of the irradiation dose in this example is 15.
0 mJ / cm 2 and resolution is 0.250 μm L & S
(Line and space). Example 53 2-Methyl-2-adamantyl methacrylate monomer and vinylhydroxyl oxime monomer were charged in a polymerization container at a ratio of 4: 6 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, A, is added to the 1,4-dioxane solution.
IBN was added in an amount of 20 mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / vinylhydroxyl oxime copolymer represented by the following formula was obtained.
【0224】[0224]
【化119】 [Chemical formula 119]
【0225】得られた共重合体は、組成比(m:n)が
66:44、重量平均分子量(Mw)が6200、そし
て分散度(Mw/Mn)が2.08であった。例54 前記例53において調製したメタクリル酸2−メチル−
2−アダマンチル/ビニルヒドロキシルオキシム共重合
体に2重量%の酸発生剤、トリフェニルスルホニウムト
リフレート(TPSSO3 CF3 )を添加し、乳酸エチ
ル(EL)に溶解した。得られたレジスト溶液を、HM
DSで前処理したシリコン基板上に膜厚0.4μmでス
ピンコートし、ホットプレート上で120℃で60秒間
プリベークした。The obtained copolymer had a composition ratio (m: n) of 66:44, a weight average molecular weight (Mw) of 6200, and a dispersity (Mw / Mn) of 2.08. Example 54 2-Methyl methacrylate prepared in Example 53 above
To the 2-adamantyl / vinylhydroxyl oxime copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added and dissolved in ethyl lactate (EL). The obtained resist solution is HM
A silicon substrate pretreated with DS was spin-coated with a film thickness of 0.4 μm, and prebaked on a hot plate at 120 ° C. for 60 seconds.
【0226】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは34.0mJ/cm2 であり、解像力は
0.275μmL&S(ライン・アンド・スペース)で
あった。例55 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ビニルカーボネートモノマを1:9の割合で重合容器に
仕込み、1モル/Lの1,4−ジオキサン溶液とした。
この1,4−ジオキサン溶液に重合開始剤、AIBNを
20モル%の量で添加し、80℃で約8時間にわたって
重合させた。重合の完結後、n−ヘキサンを沈殿剤とし
て精製を行った。次式により表されるメタクリル酸2−
メチル−2−アダマンチル/ビニルカーボネート共重合
体が得られた。After completion of the prebaking, the obtained resist film was subjected to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 34.0 mJ / cm 2 , and the resolution was 0.275 μmL & S (line and space). Example 55 2-Methyl-2-adamantyl methacrylate monomer and vinyl carbonate monomer were charged in a polymerization container at a ratio of 1: 9 to prepare a 1 mol / L 1,4-dioxane solution.
A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methacrylic acid represented by the following formula
A methyl-2-adamantyl / vinyl carbonate copolymer was obtained.
【0227】[0227]
【化120】 Embedded image
【0228】得られた共重合体は、組成比(m:n)が
82:18、重量平均分子量(Mw)が9300、そし
て分散度(Mw/Mn)が1.99であった。例56 前記例55において調製したメタクリル酸2−メチル−
2−アダマンチル/ビニルカーボネート共重合体に2重
量%の酸発生剤、トリフェニルスルホニウムトリフレー
ト(TPSSO3 CF3 )を添加し、乳酸エチル(E
L)に溶解した。得られたレジスト溶液を、HMDSで
前処理したシリコン基板上に膜厚0.4μmでスピンコ
ートし、ホットプレート上で120℃で60秒間プリベ
ークした。The obtained copolymer had a composition ratio (m: n) of 82:18, a weight average molecular weight (Mw) of 9300, and a dispersity (Mw / Mn) of 1.99. Example 56 2-Methyl methacrylate prepared in Example 55 above
To the 2-adamantyl / vinyl carbonate copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added, and ethyl lactate (E
L). The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0229】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは31.0mJ/cm2 であり、解像力は
0.275μmL&S(ライン・アンド・スペース)で
あった。例57 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ビニルアザラクトンモノマを7:3の割合で重合容器に
仕込み、1モル/Lの1,4−ジオキサン溶液とした。
この1,4−ジオキサン溶液に重合開始剤、AIBNを
20モル%の量で添加し、80℃で約8時間にわたって
重合させた。重合の完結後、n−ヘキサンを沈殿剤とし
て精製を行った。次式により表されるメタクリル酸2−
メチル−2−アダマンチル/ビニルアザラクトン共重合
体が得られた。After completion of the prebaking, the obtained resist film was subjected to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 31.0 mJ / cm 2 and the resolution was 0.275 μmL & S (line and space). Example 57 2-Methyl-2-adamantyl methacrylate monomer and vinyl azalactone monomer were charged in a polymerization container at a ratio of 7: 3 to prepare a 1 mol / L 1,4-dioxane solution.
A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methacrylic acid represented by the following formula
A methyl-2-adamantyl / vinylazalactone copolymer was obtained.
【0230】[0230]
【化121】 [Chemical 121]
【0231】得られた共重合体は、組成比(m:n)が
71:29、重量平均分子量(Mw)が10200、そ
して分散度(Mw/Mn)が1.61であった。例58 前記例57において調製したメタクリル酸2−メチル−
2−アダマンチル/ビニルアザラクトン共重合体に2重
量%の酸発生剤、トリフェニルスルホニウムトリフレー
ト(TPSSO3 CF3 )を添加し、乳酸エチル(E
L)に溶解した。得られたレジスト溶液を、HMDSで
前処理したシリコン基板上に膜厚0.4μmでスピンコ
ートし、ホットプレート上で120℃で60秒間プリベ
ークした。The obtained copolymer had a composition ratio (m: n) of 71:29, a weight average molecular weight (Mw) of 10200 and a dispersity (Mw / Mn) of 1.61. Example 58 2-Methyl methacrylate prepared in Example 57 above
To the 2-adamantyl / vinylazalactone copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added, and ethyl lactate (E
L). The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0232】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは28.2mJ/cm2 であり、解像力
は0.250μm L&S(ライン・アンド・スペー
ス)であった。例59 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ビニルオキサジンモノマを7:3の割合で重合容器に仕
込み、1モル/Lの1,4−ジオキサン溶液とした。こ
の1,4−ジオキサン溶液に重合開始剤、AIBNを2
0モル%の量で添加し、80℃で約8時間にわたって重
合させた。重合の完結後、n−ヘキサンを沈殿剤として
精製を行った。次式により表されるメタクリル酸2−メ
チル−2−アダマンチル/ビニルオキサジン共重合体が
得られた。After the completion of prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
It was developed for 60 seconds with an 8 wt% TMAH aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 28.2 mJ / cm 2 , and the resolution was 0.250 μm L & S (line and space). Example 59 2-Methyl-2-adamantyl methacrylate monomer and vinyl oxazine monomer were charged in a polymerization container at a ratio of 7: 3 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to the 1,4-dioxane solution in an amount of 2
It was added in an amount of 0 mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / vinyloxazine copolymer represented by the following formula was obtained.
【0233】[0233]
【化122】 [Chemical formula 122]
【0234】得られた共重合体は、組成比(m:n)が
70:30、重量平均分子量(Mw)が11000、そ
して分散度(Mw/Mn)が1.59であった。例60 前記例59において調製したメタクリル酸2−メチル−
2−アダマンチル/ビニルオキサジン共重合体に2重量
%の酸発生剤、トリフェニルスルホニウムトリフレート
(TPSSO3 CF3 )を添加し、乳酸エチル(EL)
に溶解した。得られたレジスト溶液を、HMDSで前処
理したシリコン基板上に膜厚0.4μmでスピンコート
し、ホットプレート上で120℃で60秒間プリベーク
した。The obtained copolymer had a composition ratio (m: n) of 70:30, a weight average molecular weight (Mw) of 11,000 and a dispersity (Mw / Mn) of 1.59. Example 60 2-Methyl methacrylate prepared in Example 59 above
To the 2-adamantyl / vinyloxazine copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added, and ethyl lactate (EL) was added.
Was dissolved. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0235】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは27.5mJ/cm2 であり、解像力
は0.250μm L&S(ライン・アンド・スペー
ス)であった。例61 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ビニルピロリドンモノマを7:3の割合で重合容器に仕
込み、1モル/Lの1,4−ジオキサン溶液とした。こ
の1,4−ジオキサン溶液に重合開始剤、AIBNを2
0モル%の量で添加し、80℃で約8時間にわたって重
合させた。重合の完結後、n−ヘキサンを沈殿剤として
精製を行った。次式により表されるメタクリル酸2−メ
チル−2−アダマンチル/ビニルピロニドン共重合体が
得られた。After completion of the prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
It was developed for 60 seconds with an 8 wt% TMAH aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 27.5 mJ / cm 2 , and the resolution was 0.250 μm L & S (line and space). Example 61 2-Methyl-2-adamantyl methacrylate monomer and vinylpyrrolidone monomer were charged in a polymerization container at a ratio of 7: 3 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to the 1,4-dioxane solution in an amount of 2
It was added in an amount of 0 mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / vinylpyrrolidone copolymer represented by the following formula was obtained.
【0236】[0236]
【化123】 [Chemical 123]
【0237】得られた共重合体は、組成比(m:n)が
68:32、重量平均分子量(Mw)が9000、そし
て分散度(Mw/Mn)が1.89であった。例62 前記例61において調製したメタクリル酸2−メチル−
2−アダマンチル/ビニルピロニドン共重合体に2重量
%の酸発生剤、トリフェニルスルホニウムトリフレート
(TPSSO3 CF3 )を添加し、乳酸エチル(EL)
に溶解した。得られたレジスト溶液を、HMDSで前処
理したシリコン基板上に膜厚0.4μmでスピンコート
し、ホットプレート上で120℃で60秒間プリベーク
した。The obtained copolymer had a composition ratio (m: n) of 68:32, a weight average molecular weight (Mw) of 9,000 and a dispersity (Mw / Mn) of 1.89. Example 62 2-Methyl methacrylate prepared in Example 61 above
2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added to a 2-adamantyl / vinylpyrrolidone copolymer and ethyl lactate (EL) was added.
Was dissolved. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0238】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を0.11
8重量%のTMAH水溶液で60秒間現像し、さらに純
水で30秒間リンスした。露光に用いたレーザ光パター
ンに相当する所望のレジストパターンがパターンの剥れ
を生じることなく得られた。なお、本例での照射線量の
闘値エネルギEthは30.5mJ/cm2 であり、解像力
は0.275μm L&S(ライン・アンド・スペー
ス)であった。例63 メタクリル酸2−メチル−2−アダマンチルモノマ及び
アクリロニトリルモノマを1:1の割合で重合容器に仕
込み、1モル/Lの1,4−ジオキサン溶液とした。こ
の1,4−ジオキサン溶液に重合開始剤、AIBNを2
0モル%の量で添加し、80℃で約8時間にわたって重
合させた。重合の完結後、n−ヘキサンを沈殿剤として
精製を行った。次式により表されるメタクリル酸2−メ
チル−2−アダマンチル/アクリロニトリル共重合体が
得られた。After completion of the prebaking, the obtained resist film was subjected to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is 0.11
It was developed for 60 seconds with an 8 wt% TMAH aqueous solution, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 30.5 mJ / cm 2 , and the resolution was 0.275 μm L & S (line and space). Example 63 2-Methyl-2-adamantyl methacrylate monomer and acrylonitrile monomer were charged into a polymerization vessel at a ratio of 1: 1 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to the 1,4-dioxane solution in an amount of 2
It was added in an amount of 0 mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / acrylonitrile copolymer represented by the following formula was obtained.
【0239】[0239]
【化124】 Embedded image
【0240】得られた共重合体は、組成比(m:n)が
80:20、重量平均分子量(Mw)が6000、そし
て分散度(Mw/Mn)が2.35であった。例64 前記例63において調製したメタクリル酸2−メチル−
2−アダマンチル/アクリロニトリル共重合体に2重量
%の酸発生剤、トリフェニルスルホニウムトリフレート
(TPSSO3 CF3 )を添加し、シクロヘキサノンに
溶解した。得られたレジスト溶液を、HMDSで前処理
したシリコン基板上に膜厚0.4μmでスピンコート
し、ホットプレート上で120℃で60秒間プリベーク
した。The obtained copolymer had a composition ratio (m: n) of 80:20, a weight average molecular weight (Mw) of 6000 and a dispersity (Mw / Mn) of 2.35. Example 64 2-Methyl methacrylate prepared in Example 63 above
To the 2-adamantyl / acrylonitrile copolymer, 2% by weight of an acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ) was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0241】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは38.2mJ/cm2 であり、解像力は
0.275μmL&S(ライン・アンド・スペース)で
あった。例65 メタクリル酸2−メチル−2−アダマンチルモノマ及び
ニトロスチレンモノマを7:3の割合で重合容器に仕込
み、1モル/Lの1,4−ジオキサン溶液とした。この
1,4−ジオキサン溶液に重合開始剤、AIBNを20
モル%の量で添加し、80℃で約8時間にわたって重合
させた。重合の完結後、n−ヘキサンを沈殿剤として精
製を行った。次式により表されるメタクリル酸2−メチ
ル−2−アダマンチル/ニトロスチレン共重合体が得ら
れた。After completion of the prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 38.2 mJ / cm 2 , and the resolution was 0.275 μmL & S (line and space). Example 65 2-Methyl-2-adamantyl methacrylate monomer and nitrostyrene monomer were charged into a polymerization vessel at a ratio of 7: 3 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, is added to the 1,4-dioxane solution in an amount of 20
It was added in an amount of mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / nitrostyrene copolymer represented by the following formula was obtained.
【0242】[0242]
【化125】 Embedded image
【0243】得られた共重合体は、組成比(m:n)が
74:26、重量平均分子量(Mw)が14000、そ
して分散度(Mw/Mn)が1.79であった。例66 前記例65において調製したメタクリル酸2−メチル−
2−アダマンチル/ニトロスチレン共重合体に2重量%
の酸発生剤、トリフェニルスルホニウムトリフレート
(TPSSO3 CF3 )を添加し、シクロヘキサノンに
溶解した。得られたレジスト溶液を、HMDSで前処理
したシリコン基板上に膜厚0.4μmでスピンコート
し、ホットプレート上で120℃で60秒間プリベーク
した。The obtained copolymer had a composition ratio (m: n) of 74:26, a weight average molecular weight (Mw) of 14,000 and a dispersity (Mw / Mn) of 1.79. Example 66 2-Methyl methacrylate prepared in Example 65 above
2% by weight in 2-adamantyl / nitrostyrene copolymer
Acid generator, triphenylsulfonium triflate (TPSSO 3 CF 3 ), was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0244】プリベークの完了後、得られたレジスト膜
をKrFエキシマステッパ(NA=0.45)で波長2
48nmのKrFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは37.5mJ/cm2 であり、解像力は
0.275μmL&S(ライン・アンド・スペース)で
あった。例67 メタクリル酸2−メチル−2−アダマンチルモノマ及び
アクロレインモノマを1:1の割合で重合容器に仕込
み、1モル/Lの1,4−ジオキサン溶液とした。この
1,4−ジオキサン溶液に重合開始剤、AIBNを20
モル%の量で添加し、80℃で約8時間にわたって重合
させた。重合の完結後、n−ヘキサンを沈殿剤として精
製を行った。次式により表されるメタクリル酸2−メチ
ル−2−アダマンチル/アクロレイン共重合体が得られ
た。After the completion of prebaking, the obtained resist film was exposed to a wavelength of 2 with a KrF excimer stepper (NA = 0.45).
It was selectively exposed to a pattern of 48 nm KrF laser light. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 37.5 mJ / cm 2 , and the resolving power was 0.275 μmL & S (line and space). Example 67 2-Methyl-2-adamantyl methacrylate monomer and acrolein monomer were charged into a polymerization vessel at a ratio of 1: 1 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, is added to the 1,4-dioxane solution in an amount of 20
It was added in an amount of mol% and polymerized at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. A 2-methyl-2-adamantyl methacrylate / acrolein copolymer represented by the following formula was obtained.
【0245】[0245]
【化126】 [Chemical formula 126]
【0246】得られた共重合体は、組成比(m:n)が
70:30、重量平均分子量(Mw)が10000、そ
して分散度(Mw/Mn)が2.10であった。例68 前記例67において調製したメタクリル酸2−メチル−
2−アダマンチル/アクロレイン共重合体に2重量%の
酸発生剤、トリフェニルスルホニウムトリフレート(T
PSSO3 CF3 )を添加し、シクロヘキサノンに溶解
した。得られたレジスト溶液を、HMDSで前処理した
シリコン基板上に膜厚0.4μmでスピンコートし、ホ
ットプレート上で120℃で60秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 70:30, a weight average molecular weight (Mw) of 10,000, and a dispersity (Mw / Mn) of 2.10. Example 68 2-Methyl methacrylate prepared in Example 67 above
2-adamantyl / acrolein copolymer with 2% by weight of acid generator, triphenylsulfonium triflate (T
PSSO 3 CF 3 ) was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0247】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは1.4mJ/cm2 であり、解像力は
0.170μmL&S(ライン・アンド・スペース)で
あった。例69 前記例68に記載の手法を繰り返した。但し、本例で
は、ArFエキシマ露光装置に代えてKrFエキシマス
テッパ(NA=0.45)を露光装置として使用し、波
長248nmのKrFレーザ光で選択露光を行った。露光
に用いたレーザ光パターンに相当する所望のレジストパ
ターンがパターンの剥れを生じることなく得られた。な
お、本例での照射線量の闘値エネルギEthは21.0
mJ/cm2 であり、解像力は0.250μm L&S(ラ
イン・アンド・スペース)であった。例70 メタクリル酸2−メチル−2−アダマンチルモノマ及び
酢酸ビニルモノマを7:3の割合で重合容器に仕込み、
1モル/Lの1,4−ジオキサン溶液とした。この1,
4−ジオキサン溶液に重合開始剤、AIBNを20モル
%の量で添加し、80℃で約8時間にわたって重合させ
た。重合の完結後、n−ヘキサンを沈殿剤として精製を
行った。次式により表されるメタクリル酸2−メチル−
2−アダマンチル/酢酸ビニル共重合体が得られた。After the completion of prebaking, the obtained resist film was irradiated with an ArF excimer exposure device (NA = 0.55) at a wavelength of 1.
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 1.4 mJ / cm 2 , and the resolution was 0.170 μmL & S (line and space). Example 69 The procedure described in Example 68 above was repeated. However, in this example, a KrF excimer stepper (NA = 0.45) was used as an exposure device in place of the ArF excimer exposure device, and selective exposure was performed with KrF laser light having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 21.0.
It was mJ / cm 2 and the resolution was 0.250 μm L & S (line and space). Example 70 2-Methyl-2-adamantyl methacrylate monomer and vinyl acetate monomer were charged in a polymerization container at a ratio of 7: 3,
A 1 mol / L 1,4-dioxane solution was prepared. This one
A polymerization initiator, AIBN, was added to the 4-dioxane solution in an amount of 20 mol%, and polymerization was performed at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. 2-methylmethacrylate represented by the following formula
A 2-adamantyl / vinyl acetate copolymer was obtained.
【0248】[0248]
【化127】 Embedded image
【0249】得られた共重合体は、組成比(m:n)が
74:26、重量平均分子量(Mw)が8200、そし
て分散度(Mw/Mn)が1.82であった。例71 前記例70において調製したメタクリル酸2−メチル−
2−アダマンチル/酢酸ビニル共重合体に2重量%の酸
発生剤、トリフェニルスルホニウムトリフレート(TP
SSO3 CF3 )を添加し、シクロヘキサノンに溶解し
た。得られたレジスト溶液を、HMDSで前処理したシ
リコン基板上に膜厚0.4μmでスピンコートし、ホッ
トプレート上で120℃で60秒間プリベークした。The obtained copolymer had a composition ratio (m: n) of 74:26, a weight average molecular weight (Mw) of 8200, and a dispersity (Mw / Mn) of 1.82. Example 71 2-Methyl methacrylate prepared in Example 70 above
2-adamantyl / vinyl acetate copolymer with 2% by weight of acid generator, triphenylsulfonium triflate (TP
SSO 3 CF 3 ) was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0250】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは2.2mJ/cm2 であり、解像力は
0.170μmL&S(ライン・アンド・スペース)で
あった。例72 前記例71に記載の手法を繰り返した。但し、本例で
は、ArFエキシマ露光装置に代えてKrFエキシマス
テッパ(NA=0.45)を露光装置として使用し、波
長248nmのKrFレーザ光で選択露光を行った。露光
に用いたレーザ光パターンに相当する所望のレジストパ
ターンがパターンの剥れを生じることなく得られた。な
お、本例での照射線量の闘値エネルギEthは22.0
mJ/cm2 であり、解像力は0.250μm L&S(ラ
イン・アンド・スペース)であった。例73 イタコン酸−α−2−メチル−2−アダマンチル−β−
メチルモノマを重合容器に仕込み、1モル/Lの1,4
−ジオキサン溶液とした。この1,4−ジオキサン溶液
に重合開始剤、AIBNを20モル%の量で添加し、8
0℃で約8時間にわたって重合させた。重合の完結後、
メタノールを沈殿剤として精製を行った。次式により表
されるイタコン酸−α−2−メチル−2−アダマンチル
−β−メチル重合体が得られた。After completion of the prebaking, the obtained resist film was irradiated with an ArF excimer exposure device (NA = 0.55) at a wavelength of 1.
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 2.2 mJ / cm 2 , and the resolution was 0.170 μmL & S (line and space). Example 72 The procedure described in Example 71 above was repeated. However, in this example, a KrF excimer stepper (NA = 0.45) was used as an exposure device in place of the ArF excimer exposure device, and selective exposure was performed with KrF laser light having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 22.0.
It was mJ / cm 2 and the resolution was 0.250 μm L & S (line and space). Example 73 Itaconic acid-α-2-methyl-2-adamantyl-β-
Charge methyl monomer into a polymerization vessel and add 1 mol / L of 1,4.
A dioxane solution. A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and 8
Polymerization was carried out at 0 ° C. for about 8 hours. After completion of polymerization,
Purification was performed using methanol as a precipitant. An itaconic acid-α-2-methyl-2-adamantyl-β-methyl polymer represented by the following formula was obtained.
【0251】[0251]
【化128】 [Chemical 128]
【0252】得られた重合体は、重量平均分子量(M
w)が18000、そして分散度(Mw/Mn)が1.
66であった。例74 前記例73において調製したイタコン酸−α−2−メチ
ル−2−アダマンチル−β−メチル重合体に2重量%の
酸発生剤、トリフェニルスルホニウムトリフレート(T
PSSO3 CF3 )を添加し、シクロヘキサノンに溶解
した。得られたレジスト溶液を、HMDSで前処理した
シリコン基板上に膜厚0.4μmでスピンコートし、ホ
ットプレート上で120℃で60秒間プリベークした。The obtained polymer had a weight average molecular weight (M
w) is 18,000 and the dispersity (Mw / Mn) is 1.
66. Example 74 Itaconic acid-α-2-methyl-2-adamantyl-β-methyl polymer prepared in Example 73 above was added with 2% by weight of an acid generator, triphenylsulfonium triflate (T.
PSSO 3 CF 3 ) was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate.
【0253】プリベークの完了後、得られたレジスト膜
をArFエキシマ露光装置(NA=0.55)で波長1
93nmのArFレーザ光のパターンに選択露光した。続
いて、露光後のレジスト膜を150℃で60秒間PEB
(露光後ベーク)した。その後、レジスト膜を2.38
重量%のTMAH水溶液で60秒間現像し、さらに純水
で30秒間リンスした。露光に用いたレーザ光パターン
に相当する所望のレジストパターンがパターンの剥れを
生じることなく得られた。なお、本例での照射線量の闘
値エネルギEthは2.0mJ/cm2 であり、解像力は
0.175μmL&S(ライン・アンド・スペース)で
あった。例75 前記例74に記載の手法を繰り返した。但し、本例で
は、ArFエキシマ露光装置に代えてKrFエキシマス
テッパ(NA=0.45)を露光装置として使用し、波
長248nmのKrFレーザ光で選択露光を行った。露光
に用いたレーザ光パターンに相当する所望のレジストパ
ターンがパターンの剥れを生じることなく得られた。な
お、本例での照射線量の闘値エネルギEthは28.5
mJ/cm2 であり、解像力は0.275μm L&S(ラ
イン・アンド・スペース)であった。例76 フマル酸ビス−2−メチル−2−アダマンチルモノマ及
びフマル酸モノマをモル比で9:1の割合で重合容器に
仕込み、1モル/Lの1,4−ジオキサン溶液とした。
この1,4−ジオキサン溶液に重合開始剤、AIBNを
20モル%の量で添加し、80℃で約8時間にわたって
重合させた。重合の完結後、n−ヘキサンを沈殿剤とし
て精製を行った。次式により表されるフマル酸ビス−2
−メチル−2−アダマンチル/フマル酸共重合体が得ら
れた。After completion of the prebaking, the obtained resist film was irradiated with a wavelength of 1 using an ArF excimer exposure device (NA = 0.55).
The pattern was selectively exposed to a 93 nm ArF laser beam pattern. Next, the exposed resist film is PEB at 150 ° C. for 60 seconds.
(Bake after exposure). After that, the resist film is set to 2.38.
Development was carried out for 60 seconds with a TMAH aqueous solution of wt%, and further rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example was 2.0 mJ / cm 2 , and the resolution was 0.175 μmL & S (line and space). Example 75 The procedure described in Example 74 above was repeated. However, in this example, a KrF excimer stepper (NA = 0.45) was used as an exposure device in place of the ArF excimer exposure device, and selective exposure was performed with KrF laser light having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 28.5.
It was mJ / cm 2 and the resolution was 0.275 μm L & S (line and space). Example 76 Bis-2-methyl-2-adamantyl fumarate monomer and fumarate monomer were charged in a polymerization container at a molar ratio of 9: 1 to prepare a 1 mol / L 1,4-dioxane solution.
A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and polymerization was carried out at 80 ° C. for about 8 hours. After completion of the polymerization, purification was performed using n-hexane as a precipitating agent. Bis-2 fumarate represented by the following formula
A -methyl-2-adamantyl / fumaric acid copolymer was obtained.
【0254】[0254]
【化129】 [Chemical formula 129]
【0255】得られた共重合体は、組成比(m:n)が
95:5、重量平均分子量(Mw)が5100、そして
分散度(Mw/Mn)が2.84であった。例77 前記例76において調製したフマル酸ビス−2−メチル
−2−アダマンチル/フマル酸共重合体に2重量%の酸
発生剤、トリフェニルスルホニウムトリフレート(TP
SSO3 CF3 )を添加し、シクロヘキサノンに溶解し
た。得られたレジスト溶液を、HMDSで前処理したシ
リコン基板上に膜厚0.4μmでスピンコートし、ホッ
トプレート上で120℃で60秒間プリベークした。プ
リベークの完了後、得られたレジスト膜をArFエキシ
マ露光装置(NA=0.55)で波長193nmのArF
レーザ光のパターンに選択露光した。続いて、露光後の
レジスト膜を150℃で60秒間PEB(露光後ベー
ク)した。その後、レジスト膜を0.118重量%のT
MAH水溶液で60秒間現像し、さらに純水で30秒間
リンスした。露光に用いたレーザ光パターンに相当する
所望のレジストパターンがパターンの剥れを生じること
なく得られた。なお、本例での照射線量の闘値エネルギ
Ethは2.8mJ/cm2 であり、解像力は0.180μ
mL&S(ライン・アンド・スペース)であった。例78 前記例77に記載の手法を繰り返した。但し、本例で
は、ArFエキシマ露光装置に代えてKrFエキシマス
テッパ(NA=0.45)を露光装置として使用し、波
長248nmのKrFレーザ光で選択露光を行った。露光
に用いたレーザ光パターンに相当する所望のレジストパ
ターンがパターンの剥れを生じることなく得られた。な
お、本例での照射線量の闘値エネルギEthは30.5
mJ/cm2 であり、解像力は0.275μm L&S(ラ
イン・アンド・スペース)であった。例79 2−メチルアダマンチルメタクリレート及びメタクリル
酸をモル比で9:1の割合で重合容器に仕込み、1モル
/Lの1,4−ジオキサン溶液とした。この1,4−ジ
オキサン溶液に重合開始剤、AIBNを20モル%の量
で添加し、80℃で約7時間にわたって保持させた。そ
の後、この反応系をテトラヒドロフラン(THF)に溶
解し、得られた溶液を大量のメタノール中に投入し、沈
殿物を濾別した。2−メチルアダマンチルメタクリレー
ト/メタクリル酸共重合体が収率44%で得られた。得
られた共重合体は、組成比が9:1で、重量平均分子量
(Mw)が9600であった。例80 前記例79において調製した2−メチルアダマンチルメ
タクリレート/メタクリル酸共重合体に5重量%の酸発
生剤、トリフェニルスルホニウムヘキサフルオロアンチ
モネート(TPSSbF4 )を添加し、樹脂分が全量の
15重量%になるようにシクロヘキサノンに溶解した。
得られたレジスト溶液を、HMDSで前処理したシリコ
ン基板上に膜厚0.7μmでスピンコートした。The obtained copolymer had a composition ratio (m: n) of 95: 5, a weight average molecular weight (Mw) of 5100, and a dispersity (Mw / Mn) of 2.84. Example 77 Bis-2-methyl-2-adamantyl fumarate / fumaric acid copolymer prepared in Example 76 above was added with 2% by weight of an acid generator, triphenylsulfonium triflate (TP).
SSO 3 CF 3 ) was added and dissolved in cyclohexanone. The obtained resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.4 μm, and prebaked at 120 ° C. for 60 seconds on a hot plate. After the completion of prebaking, the obtained resist film was exposed to ArF excimer exposure apparatus (NA = 0.55) at a wavelength of 193 nm.
A pattern of laser light was selectively exposed. Subsequently, the resist film after exposure was subjected to PEB (post-exposure bake) at 150 ° C. for 60 seconds. After that, the resist film is coated with 0.118% by weight of T
It was developed for 60 seconds with an MAH aqueous solution and further rinsed for 30 seconds with pure water. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 2.8 mJ / cm 2 , and the resolution is 0.180 μm.
It was mL & S (line and space). Example 78 The procedure described in Example 77 above was repeated. However, in this example, a KrF excimer stepper (NA = 0.45) was used as an exposure device in place of the ArF excimer exposure device, and selective exposure was performed with KrF laser light having a wavelength of 248 nm. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. The threshold energy Eth of the irradiation dose in this example is 30.5.
It was mJ / cm 2 and the resolution was 0.275 μm L & S (line and space). Example 79 2-Methyladamantyl methacrylate and methacrylic acid were charged in a polymerization container at a molar ratio of 9: 1 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to the 1,4-dioxane solution in an amount of 20 mol%, and the mixture was kept at 80 ° C. for about 7 hours. Then, this reaction system was dissolved in tetrahydrofuran (THF), the obtained solution was put into a large amount of methanol, and the precipitate was separated by filtration. A 2-methyladamantyl methacrylate / methacrylic acid copolymer was obtained with a yield of 44%. The obtained copolymer had a composition ratio of 9: 1 and a weight average molecular weight (Mw) of 9,600. Example 80 To the 2-methyladamantyl methacrylate / methacrylic acid copolymer prepared in Example 79 above, 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate (TPSSbF 4 ) was added, and the resin content was 15% by weight. It was dissolved in cyclohexanone so that the concentration became%.
The resulting resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.7 μm.
【0256】得られたレジスト膜をKrFエキシマステ
ッパ(NA=0.45)で波長248nmのKrFレーザ
光のパターンにマスクを介して選択露光した。そして、
露光直後、レジスト膜を150℃のホットプレート上で
60秒間PEB(露光後ベーク)した。その後、レジス
ト膜を2.38重量%のTMAH水溶液で60秒間現像
し、さらに純水で30秒間リンスした。露光に用いたレ
ーザ光パターンに相当する所望のレジストパターンがパ
ターンの剥れを生じることなく得られた。0.25μm
L&S(ライン・アンド・スペース)パターンをほぼ
1:1に解像した。The obtained resist film was selectively exposed with a KrF excimer stepper (NA = 0.45) to a pattern of KrF laser light having a wavelength of 248 nm through a mask. And
Immediately after the exposure, the resist film was PEB (post-exposure baked) on a hot plate at 150 ° C. for 60 seconds. Then, the resist film was developed with a 2.38 wt% TMAH aqueous solution for 60 seconds, and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.25 μm
The L & S (line and space) pattern was resolved almost 1: 1.
【0257】さらに、上記のようにして形成したレジス
ト膜をKrFエキシマステッパで0.325μm のホー
ルパターンに露光した。この場合にも、露光に用いたレ
ーザ光パターンに相当する0.325μm のホールレジ
ストパターンが得られた。例81 前記例80に記載の手法を繰り返した。但し、本例で
は、酸発生剤、TPSSbF4 の添加量を5重量%から
2重量%に変更し、さらに、レジスト膜の膜厚を0.7
μmから0.4μm に、露光装置をKrFエキシマステ
ッパからArFエキシマ露光装置、波長193nm(NA
=0.55)に、それぞれ変更した。露光に用いたレー
ザ光パターンに相当する所望のレジストパターンがパタ
ーンの剥れを生じることなく得られた。0.18μm
L&S(ライン・アンド・スペース)パターンをほぼ
1:1に解像した。例82 2−メチルアダマンチルメタクリレート、t−ブチルメ
タクリル酸及びメタクリル酸をモル比で40:35:2
5の割合で重合容器に仕込み、1モル/Lの1,4−ジ
オキサン溶液とした。この1,4−ジオキサン溶液に重
合開始剤、AIBNを20モル%の量で添加し、80℃
で約7時間にわたって保持させた。その後、この反応系
をテトラヒドロフラン(THF)に溶解し、得られた溶
液を大量のn−ヘキサン中に投入し、沈殿物を濾別し
た。2−メチルアダマンチルメタクリレート/t−ブチ
ルメタクリル酸/メタクリル酸共重合体が収率58%で
得られた。得られた共重合体は、組成比が50:29:
21で、重量平均分子量(Mw)が12000であっ
た。例83 前記例82において調製した2−メチルアダマンチルメ
タクリレート/t−ブチルメタクリル酸/メタクリル酸
共重合体に5重量%の酸発生剤、トリフェニルスルホニ
ウムヘキサフルオロアンチモネート(TPSSbF4 )
を添加し、樹脂分が全量の15重量%になるようにシク
ロヘキサノンに溶解した。得られたレジスト溶液を、H
MDSで前処理したシリコン基板上に膜厚0.7μmで
スピンコートした。Further, the resist film formed as described above was exposed to a 0.325 μm hole pattern by a KrF excimer stepper. Also in this case, a 0.325 μm hole resist pattern corresponding to the laser beam pattern used for exposure was obtained. Example 81 The procedure described in Example 80 above was repeated. However, in this example, the addition amount of the acid generator and TPSSbF 4 was changed from 5% by weight to 2% by weight, and the film thickness of the resist film was 0.7%.
From μm to 0.4 μm, change the exposure equipment from KrF excimer stepper to ArF excimer exposure equipment, wavelength 193 nm (NA
= 0.55). A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.18 μm
The L & S (line and space) pattern was resolved almost 1: 1. Example 82 2-Methyladamantyl methacrylate, t-butyl methacrylic acid and methacrylic acid in a molar ratio of 40: 35: 2.
It was charged into a polymerization vessel at a ratio of 5 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%, and the mixture was heated at 80 ° C.
Held for about 7 hours. Then, this reaction system was dissolved in tetrahydrofuran (THF), the obtained solution was put into a large amount of n-hexane, and the precipitate was separated by filtration. A 2-methyladamantyl methacrylate / t-butyl methacrylic acid / methacrylic acid copolymer was obtained with a yield of 58%. The resulting copolymer had a composition ratio of 50:29:
21, the weight average molecular weight (Mw) was 12000. Example 83 The 2-methyladamantyl methacrylate / t-butyl methacrylic acid / methacrylic acid copolymer prepared in Example 82 above was added with 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate (TPSSbF 4 ).
Was added and dissolved in cyclohexanone so that the resin content was 15% by weight of the total amount. The obtained resist solution is
A silicon substrate pretreated with MDS was spin-coated with a film thickness of 0.7 μm.
【0258】得られたレジスト膜をKrFエキシマステ
ッパ(NA=0.45)で波長248nmのKrFレーザ
光のパターンにマスクを介して選択露光した。そして、
露光直後、レジスト膜を130℃のホットプレート上で
60秒間PEB(露光後ベーク)した。その後、レジス
ト膜を0.17重量%のTMAH水溶液で60秒間現像
し、さらに純水で30秒間リンスした。露光に用いたレ
ーザ光パターンに相当する所望のレジストパターンがパ
ターンの剥れを生じることなく得られた。0.25μm
L&S(ライン・アンド・スペース)パターンをほぼ
1:1に解像した。The obtained resist film was selectively exposed with a KrF excimer stepper (NA = 0.45) to a pattern of KrF laser light having a wavelength of 248 nm through a mask. And
Immediately after the exposure, the resist film was subjected to PEB (post-exposure bake) for 60 seconds on a hot plate at 130 ° C. Then, the resist film was developed with a 0.17 wt% TMAH aqueous solution for 60 seconds and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.25 μm
The L & S (line and space) pattern was resolved almost 1: 1.
【0259】さらに、上記のようにして形成したレジス
ト膜をKrFエキシマステッパで0.325μm のホー
ルパターンに露光した。この場合にも、露光に用いたレ
ーザ光パターンに相当する0.325μm のホールレジ
ストパターンが得られた。例84 前記例83に記載の手法を繰り返した。但し、本例で
は、酸発生剤、TPSSbF4 の添加量を5重量%から
2重量%に、露光装置をKrFエキシマステッパからA
rFエキシマ露光装置、波長193nm(NA=0.5
5)に、それぞれ変更した。露光に用いたレーザ光パタ
ーンに相当する所望のレジストパターンがパターンの剥
れを生じることなく得られた。0.19μm L&S
(ライン・アンド・スペース)パターンをほぼ1:1に
解像した。例85 2−メチルアダマンチルメタクリレート、3−オキソシ
クロヘキシルメタクリレート及びメタクリル酸をモル比
で50:35:15の割合で重合容器に仕込み、1モル
/Lの1,4−ジオキサン溶液とした。この1,4−ジ
オキサン溶液に重合開始剤、AIBNを20モル%の量
で添加し、80℃で約7時間にわたって保持させた。そ
の後、この反応系をテトラヒドロフラン(THF)に溶
解し、得られた溶液を大量のメタノール及び水の混合溶
媒(10:1)中に投入し、沈殿物を濾別した。2−メ
チルアダマンチルメタクリレート/3−オキソシクロヘ
キシルメタクリレート/メタクリル酸共重合体が収率4
3%で得られた。得られた共重合体は、組成比が50:
35:15で、重量平均分子量(Mw)が11000で
あった。例86 前記例85において調製した2−メチルアダマンチルメ
タクリレート/3−オキソシクロヘキシルメタクリレー
ト/メタクリル酸共重合体に5重量%の酸発生剤、トリ
フェニルスルホニウムヘキサフルオロアンチモネート
(TPSSbF4)を添加し、樹脂分が全量の15重量
%になるようにシクロヘキサノンに溶解した。得られた
レジスト溶液を、HMDSで前処理したシリコン基板上
に膜厚0.7μmでスピンコートした。Further, the resist film formed as described above was exposed with a KrF excimer stepper to a hole pattern of 0.325 μm. Also in this case, a 0.325 μm hole resist pattern corresponding to the laser beam pattern used for exposure was obtained. Example 84 The procedure described in Example 83 above was repeated. However, in this example, the amount of the acid generator and TPSSbF 4 added was changed from 5% by weight to 2% by weight, and the exposure apparatus was changed from KrF excimer stepper to A.
rF excimer exposure device, wavelength 193 nm (NA = 0.5
5), respectively. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.19 μm L & S
The (line and space) pattern was resolved almost 1: 1. Example 85 2-Methyladamantyl methacrylate, 3-oxocyclohexyl methacrylate and methacrylic acid were charged into a polymerization container at a molar ratio of 50:35:15 to prepare a 1 mol / L 1,4-dioxane solution. A polymerization initiator, AIBN, was added to the 1,4-dioxane solution in an amount of 20 mol%, and the mixture was kept at 80 ° C. for about 7 hours. Then, this reaction system was dissolved in tetrahydrofuran (THF), the obtained solution was put into a large amount of a mixed solvent of methanol and water (10: 1), and the precipitate was filtered off. 2-methyladamantyl methacrylate / 3-oxocyclohexyl methacrylate / methacrylic acid copolymer yield 4
Obtained in 3%. The obtained copolymer has a composition ratio of 50 :.
The weight average molecular weight (Mw) was 11,000 at 35:15. Example 86 To the 2-methyladamantyl methacrylate / 3-oxocyclohexyl methacrylate / methacrylic acid copolymer prepared in Example 85 above was added 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate (TPSSbF 4 ), and the resin was added. The content was dissolved in cyclohexanone so that the content was 15% by weight of the total amount. The resulting resist solution was spin-coated on a silicon substrate pretreated with HMDS to a film thickness of 0.7 μm.
【0260】得られたレジスト膜をKrFエキシマステ
ッパ(NA=0.45)で波長248nmのKrFレーザ
光のパターンにマスクを介して選択露光した。そして、
露光直後、レジスト膜を130℃のホットプレート上で
60秒間PEB(露光後ベーク)した。その後、レジス
ト膜を0.17重量%のTMAH水溶液で60秒間現像
し、さらに純水で30秒間リンスした。露光に用いたレ
ーザ光パターンに相当する所望のレジストパターンがパ
ターンの剥れを生じることなく得られた。0.25μm
L&S(ライン・アンド・スペース)パターンをほぼ
1:1に解像した。The obtained resist film was selectively exposed with a KrF excimer stepper (NA = 0.45) to a pattern of KrF laser light having a wavelength of 248 nm through a mask. And
Immediately after the exposure, the resist film was subjected to PEB (post-exposure bake) for 60 seconds on a hot plate at 130 ° C. Then, the resist film was developed with a 0.17 wt% TMAH aqueous solution for 60 seconds and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.25 μm
The L & S (line and space) pattern was resolved almost 1: 1.
【0261】さらに、上記のようにして形成したレジス
ト膜をKrFエキシマステッパで0.325μm のホー
ルパターンに露光した。この場合にも、露光に用いたレ
ーザ光パターンに相当する0.325μm のホールレジ
ストパターンが得られた。例87 前記例86に記載の手法を繰り返した。但し、本例で
は、露光装置をKrFエキシマステッパからArFエキ
シマ露光装置、波長193nm(NA=0.55)に変更
した。露光に用いたレーザ光パターンに相当する所望の
レジストパターンがパターンの剥れを生じることなく得
られた。0.19μm L&S(ライン・アンド・スペ
ース)パターンをほぼ1:1に解像した。例88 2−メチルシクロヘキシルメタクリレート、t−ブチル
メタクリレート及びメタクリル酸をモル比で40:3
5:25の割合で重合容器に仕込み、1モル/Lの1,
4−ジオキサン溶液とした。この1,4−ジオキサン溶
液に重合開始剤、AIBNを20モル%の量で添加し、
80℃で約7時間にわたって保持させた。その後、この
反応系をテトラヒドロフラン(THF)に溶解し、得ら
れた溶液を大量のn−ヘキサン中に投入し、沈殿物を濾
別した。2−メチルシクロヘキシルメタクリレート/t
−ブチルメタクリレート/メタクリル酸共重合体が収率
63%で得られた。得られた共重合体は、組成比が5
0:29:21で、重量平均分子量(Mw)が2100
0であった。例89 前記例88において調製した2−メチルシクロヘキシル
メタクリレート/t−ブチルメタクリレート/メタクリ
ル酸共重合体に5重量%の酸発生剤、トリフェニルスル
ホニウムヘキサフルオロアンチモネート(TPSSbF
4 )を添加し、樹脂分が全量の15重量%になるように
シクロヘキサノンに溶解した。得られたレジスト溶液
を、HMDSで前処理したシリコン基板上に膜厚0.7
μmでスピンコートした。Further, the resist film formed as described above was exposed to a 0.325 μm hole pattern by a KrF excimer stepper. Also in this case, a 0.325 μm hole resist pattern corresponding to the laser beam pattern used for exposure was obtained. Example 87 The procedure described in Example 86 above was repeated. However, in this example, the exposure apparatus was changed from a KrF excimer stepper to an ArF excimer exposure apparatus with a wavelength of 193 nm (NA = 0.55). A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. A 0.19 μm L & S (line and space) pattern was resolved approximately 1: 1. Example 88 2-Methylcyclohexyl methacrylate, t-butyl methacrylate and methacrylic acid in a molar ratio of 40: 3.
A polymerization container was charged at a ratio of 5:25, and 1 mol / L of 1,
This was a 4-dioxane solution. A polymerization initiator, AIBN, was added to this 1,4-dioxane solution in an amount of 20 mol%,
Hold at 80 ° C. for about 7 hours. Then, this reaction system was dissolved in tetrahydrofuran (THF), the obtained solution was put into a large amount of n-hexane, and the precipitate was separated by filtration. 2-methylcyclohexyl methacrylate / t
-Butyl methacrylate / methacrylic acid copolymer was obtained with a yield of 63%. The obtained copolymer has a composition ratio of 5
The weight average molecular weight (Mw) is 2100 at 0:29:21.
It was 0. Example 89 The 2-methylcyclohexylmethacrylate / t-butylmethacrylate / methacrylic acid copolymer prepared in Example 88 above contained 5% by weight of an acid generator, triphenylsulfonium hexafluoroantimonate (TPSSbF).
4 ) was added and dissolved in cyclohexanone so that the resin content was 15% by weight of the total amount. The obtained resist solution was applied onto a silicon substrate pretreated with HMDS to give a film thickness of 0.7.
It was spin-coated with μm.
【0262】得られたレジスト膜をKrFエキシマステ
ッパ(NA=0.45)で波長248nmのKrFレーザ
光のパターンにマスクを介して選択露光した。そして、
露光直後、レジスト膜を130℃のホットプレート上で
60秒間PEB(露光後ベーク)した。その後、レジス
ト膜を0.17重量%のTMAH水溶液で60秒間現像
し、さらに純水で30秒間リンスした。露光に用いたレ
ーザ光パターンに相当する所望のレジストパターンがパ
ターンの剥れを生じることなく得られた。0.25μm
L&S(ライン・アンド・スペース)パターンをほぼ
1:1に解像した。The obtained resist film was selectively exposed with a KrF excimer stepper (NA = 0.45) to a pattern of KrF laser light having a wavelength of 248 nm through a mask. And
Immediately after the exposure, the resist film was subjected to PEB (post-exposure bake) for 60 seconds on a hot plate at 130 ° C. Then, the resist film was developed with a 0.17 wt% TMAH aqueous solution for 60 seconds and rinsed with pure water for 30 seconds. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.25 μm
The L & S (line and space) pattern was resolved almost 1: 1.
【0263】さらに、上記のようにして形成したレジス
ト膜をKrFエキシマステッパで0.325μm のホー
ルパターンに露光した。この場合にも、露光に用いたレ
ーザ光パターンに相当する0.325μm のホールレジ
ストパターンが得られた。例90 前記例89に記載の手法を繰り返した。但し、本例で
は、酸発生剤、TPSSbF4 の添加量を5重量%から
2重量%に、露光装置をKrFエキシマステッパからA
rFエキシマ露光装置、波長193nm(NA=0.5
5)に、それぞれ変更した。露光に用いたレーザ光パタ
ーンに相当する所望のレジストパターンがパターンの剥
れを生じることなく得られた。0.19μm L&S
(ライン・アンド・スペース)パターンをほぼ1:1に
解像した。Further, the resist film formed as described above was exposed to a 0.325 μm hole pattern by a KrF excimer stepper. Also in this case, a 0.325 μm hole resist pattern corresponding to the laser beam pattern used for exposure was obtained. Example 90 The procedure described in Example 89 above was repeated. However, in this example, the amount of the acid generator and TPSSbF 4 added was changed from 5% by weight to 2% by weight, and the exposure apparatus was changed from KrF excimer stepper to A.
rF excimer exposure device, wavelength 193 nm (NA = 0.5
5), respectively. A desired resist pattern corresponding to the laser light pattern used for exposure was obtained without peeling of the pattern. 0.19 μm L & S
The (line and space) pattern was resolved almost 1: 1.
【0264】[0264]
【発明の効果】本発明によれば、上記したような化学増
幅型レジストを使用することにより、また、特に、かか
るレジストと組み合わせて特定のアンモニウム化合物又
はモルフォリン化合物の水溶液又はアルコール溶液を現
像液として使用することにより、レジスト樹脂とのなじ
みやすさ、溶解度をコントロールして、現像時に発生す
るストレスを緩和することにより、レジストパターンの
剥離やクラックの発生を低減し、安定したパターニング
特性を得ることができる。さらに、本発明によれば、現
像時に発生する歪みを緩和することにより、安定したパ
ターニング特性を得ることもできる。さらにまた、本発
明によれば、露光マージンが広くなり、安定した微細レ
ジストパターンを形成することができ、その際、下地に
対するレジストの密着性も非常に良好である。また、焼
き付けようとする回路パターンが遮光されるようにでき
た露光マスクを介して露光を行う場合に、所望のマスク
パターンよりポジ型パターンが若干大きくできあがるこ
とも防止できる。According to the present invention, by using the above chemically amplified resist, and in particular, in combination with such a resist, an aqueous solution or alcohol solution of a specific ammonium compound or morpholine compound is developed. By controlling the compatibility with the resist resin and the solubility to reduce the stress generated during development, the peeling and cracking of the resist pattern can be reduced and stable patterning characteristics can be obtained. You can Furthermore, according to the present invention, stable patterning characteristics can be obtained by relaxing the strain generated during development. Furthermore, according to the present invention, the exposure margin can be widened, and a stable fine resist pattern can be formed. At that time, the adhesion of the resist to the base is very good. It is also possible to prevent the positive pattern from being made slightly larger than the desired mask pattern when exposure is performed through an exposure mask which is designed to shield the circuit pattern to be printed.
Claims (20)
される脂環式炭化水素基含有部分: 【化1】 (上式において、RI は、1〜4個の炭素原子を有する
直鎖もしくは分岐鎖のアルキル基を表し、置換もしくは
非置換のいずれであってもよく、そしてZは、記載の炭
素原子とともに脂環式炭化水素基を完成するのに必要な
複数個の原子を表す) 【化2】 (上式において、RIIは、同一もしくは異なっていても
よく、1〜4個の炭素原子を有する置換もしくは非置換
の直鎖もしくは分岐鎖のアルキル基又は脂環式脂環式炭
化水素基を表し、但し、RIIの少なくとも1個は脂環式
炭化水素基である) 【化3】 (上式において、RIIは前記定義に同じである) 【化4】 (上式において、RIII は、同一もしくは異なっていて
もよく、プロトン、1〜4個の炭素原子を有する置換も
しくは非置換の直鎖もしくは分岐鎖のアルキル基又は脂
環式炭化水素基を表し、但し、RIII の少なくとも1個
は脂環式炭化水素基であり、また、式中、非二重結合の
炭素原子に結合した2個のRIII のうち少なくとも1個
は、1〜4個の炭素原子を有する置換もしくは非置換の
直鎖もしくは分岐鎖のアルキル基又は脂環式炭化水素基
である) 【化5】 (上式において、RIIは前記定義に同じである) 【化6】 (上式において、RI 及びZは前記定義に同じである)
で保護されたアルカリ可溶性基を有しかつ前記アルカリ
可溶性基が酸により脱離して当該化合物をアルカリ可溶
性とならしめる構造単位を含む酸感応性化合物と、放射
線露光により酸を発生する酸発生剤とを含んでなること
を特徴とするレジスト材料。1. An alicyclic hydrocarbon group-containing moiety represented by any of the following formulas (I) to (VI): (In the above formula, R I represents a linear or branched alkyl group having 1 to 4 carbon atoms, which may be substituted or unsubstituted, and Z is Represents a plurality of atoms necessary to complete an alicyclic hydrocarbon group) (In the above formula, R II may be the same or different and is a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms or an alicyclic alicyclic hydrocarbon group. Provided that at least one of R II is an alicyclic hydrocarbon group) (In the above formula, R II is the same as the above definition.) (In the above formula, R III may be the same or different and represents a proton, a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms or an alicyclic hydrocarbon group. Provided that at least one of R III is an alicyclic hydrocarbon group, and in the formula, at least one of two R III bonded to a non-double bond carbon atom is 1 to 4 A substituted or unsubstituted linear or branched alkyl group having a carbon atom of or an alicyclic hydrocarbon group) (In the above formula, R II is the same as the above definition.) (In the above formula, R I and Z are the same as defined above.)
An acid-sensitive compound having a structural unit having an alkali-soluble group protected by and having the alkali-soluble group eliminated by an acid to make the compound alkali-soluble, and an acid generator capable of generating an acid upon exposure to radiation. A resist material comprising:
基、スルホン酸基、アミド基、イミド基及びフェノール
基からなる群から選ばれる一員であることを特徴とす
る、請求項1に記載のレジスト材料。2. The resist material according to claim 1, wherein the alkali-soluble group is a member selected from the group consisting of a carboxylic acid group, a sulfonic acid group, an amide group, an imide group and a phenol group. .
式(VII )〜(XI)により表されるカルボン酸基: 【化7】 【化8】 【化9】 【化10】 【化11】 (式中、RI 、RII及びRIII ならびにZは、それぞ
れ、前記定義に同じである)、 次式(XII )により表されるイミド基: 【化12】 (式中、Zは前記定義に同じである)又は次式(XIII)
により表されるフェノール基: 【化13】 (式中、Zは前記定義に同じである)であることを特徴
とする、請求項1又は2に記載のレジスト材料。3. The protected alkali-soluble group is a carboxylic acid group represented by the following formulas (VII) to (XI): Embedded image Embedded image Embedded image Embedded image (Wherein R I , R II and R III and Z are the same as defined above), and an imide group represented by the following formula (XII): (Wherein Z is the same as the above definition) or the following formula (XIII)
Phenol group represented by: (In formula, Z is the same as said definition.) The resist material of Claim 1 or 2 characterized by the above-mentioned.
れる脂環式炭化水素基が、複数個の環構造を有するかも
しくは縮合環を有していることを特徴とする、請求項1
〜3のいずれか1項に記載のレジスト材料。4. The alicyclic hydrocarbon group contained in the protected alkali-soluble group has a plurality of ring structures or a fused ring.
4. The resist material according to any one of items 3 to 3.
の誘導体 (6)ビシクロヘキサン及びその誘導体 (7)スピロ〔4,4〕ノナン及びその誘導体 (8)スピロ〔4,5〕デカン及びその誘導体 から選ばれた1員であることを特徴とする、請求項1〜
3のいずれか1項に記載のレジスト材料。5. The alicyclic hydrocarbon group has the following groups: (1) adamantane and its derivative (2) norbornane and its derivative (3) perhydroanthracene and its derivative (4) perhydronaphthalene and its derivative (5) Tricyclo [5.2.1.0 2,6 ] decane and its derivatives (6) Bicyclohexane and its derivatives (7) Spiro [4,4] nonane and its derivatives (8) Spiro [4,5] It is one member selected from decane and its derivative, It is characterized by the above-mentioned.
4. The resist material according to any one of 3 above.
繰り返し単位として含む重合体又は共重合体であること
を特徴とする、請求項1〜5のいずれか1項に記載のレ
ジスト材料。6. The resist material according to claim 1, wherein the acid-sensitive compound is a polymer or a copolymer containing the structural unit as a repeating unit.
が、アクリル酸エステル及びその誘導体、イタコン酸エ
ステル及びその誘導体、フマル酸エステル及びその誘導
体ならびにスチレン置換体及びその誘導体からなる群か
ら選ばれる一員であることを特徴とする、請求項6に記
載のレジスト材料。7. The repeating unit of the polymer or copolymer is selected from the group consisting of acrylic acid esters and derivatives thereof, itaconic acid esters and derivatives thereof, fumaric esters and derivatives thereof, and substituted styrene and derivatives thereof. The resist material according to claim 6, wherein the resist material is a member.
繰り返し単位として含む共重合体であり、該共重合体の
残りの繰り返し単位が、アルカリ可溶性基を側鎖に有す
る繰り返し単位及び(又は)前記酸発生剤から生じる酸
により脱離可能な追加の保護されたアルカリ可溶性基を
側鎖に有する繰り返し単位を含むことを特徴とする、請
求項6に記載のレジスト材料。8. The acid-sensitive compound is a copolymer containing the structural unit as a repeating unit, and the remaining repeating unit of the copolymer has a repeating unit having an alkali-soluble group in a side chain, and / or 7. The resist material according to claim 6, comprising a repeating unit having an additional protected alkali-soluble group capable of being eliminated by an acid generated from the acid generator in a side chain.
V)により表される構造単位: 【化14】 【化15】 (上式において、Rは、同一もしくは異なっていてもよ
く、水素、ハロゲン又は1〜4個の炭素原子を有する置
換もしくは非置換の直鎖もしくは分岐鎖のアルキル基を
表し、 RI は、1〜4個の炭素原子を有する直鎖もしくは分岐
鎖のアルキル基を表し、置換もしくは非置換のいずれで
あってもよく、 Aは、酸により脱離可能な保護基を表し、そしてZは、
記載の炭素原子とともに脂環式炭化水素基を完成するの
に必要な複数個の原子を表す)を含むことを特徴とす
る、請求項8に記載のレジスト材料。9. The copolymer has the following formula (XIV) or (X
Structural unit represented by V): [Chemical 15] (In the above formulas, R may be the same or different and represents hydrogen, halogen or a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms, and R I is 1 Represents a linear or branched alkyl group having 4 to 4 carbon atoms, which may be substituted or unsubstituted, A represents an acid-eliminating protecting group, and Z represents
The resist material according to claim 8, further comprising a plurality of atoms necessary for completing the alicyclic hydrocarbon group together with the described carbon atom.
下記の群: (1)アダマンタン及びその誘導体 (2)ノルボルナン及びその誘導体 (3)パーヒドロアントラセン及びその誘導体 (4)パーヒドロナフタレン及びその誘導体 (5)トリシクロ〔5.2.1.02,6 〕デカン及びそ
の誘導体 (6)ビシクロヘキサン及びその誘導体 (7)スピロ〔4,4〕ノナン及びその誘導体 (8)スピロ〔4,5〕デカン及びその誘導体 から選ばれた一員であることを特徴とする、請求項9に
記載のレジスト材料。10. The alicyclic hydrocarbon group of the copolymer is
The following groups: (1) adamantane and its derivatives (2) norbornane and its derivatives (3) perhydroanthracene and its derivatives (4) perhydronaphthalene and its derivatives (5) tricyclo [5.2.1.0 2, 6 ] Decane and its derivatives (6) Bicyclohexane and its derivatives (7) Spiro [4,5] nonane and its derivatives (8) Spiro [4,5] decane and its derivatives The resist material according to claim 9, wherein
あり、アルカリ可溶性の重合体又は共重合体がこの化合
物に併用されることを特徴とする、請求項1〜5のいず
れか1項に記載のレジスト材料。11. The method according to claim 1, wherein the acid-sensitive compound is a non-polymerized compound, and an alkali-soluble polymer or copolymer is used in combination with the compound. The described resist material.
表される脂環式炭化水素基含有部分: 【化16】 (上式において、RI は、1〜4個の炭素原子を有する
直鎖もしくは分岐鎖のアルキル基を表し、置換もしくは
非置換のいずれであってもよく、そしてZは、記載の炭
素原子とともに脂環式炭化水素基を完成するのに必要な
複数個の原子を表す) 【化17】 (上式において、RIIは、同一もしくは異なっていても
よく、1〜4個の炭素原子を有する置換もしくは非置換
の直鎖もしくは分岐鎖のアルキル基又は脂環式脂環式炭
化水素基を表し、但し、RIIの少なくとも1個は脂環式
炭化水素基である) 【化18】 (上式において、RIIは前記定義に同じである) 【化19】 (上式において、RIII は、同一もしくは異なっていて
もよく、プロトン、1〜4個の炭素原子を有する置換も
しくは非置換の直鎖もしくは分岐鎖のアルキル基又は脂
環式炭化水素基を表し、但し、RIII の少なくとも1個
は脂環式炭化水素基であり、また、式中、非二重結合の
炭素原子に結合した2個のRIII のうち少なくとも1個
は、1〜4個の炭素原子を有する置換もしくは非置換の
直鎖もしくは分岐鎖のアルキル基又は脂環式炭化水素基
である) 【化20】 (上式において、RIIは前記定義に同じである) 【化21】 (上式において、RI 及びZは前記定義に同じである)
で保護されたアルカリ可溶性基を有しかつ前記アルカリ
可溶性基が酸により脱離して当該化合物をアルカリ可溶
性とならしめる構造単位を含む酸感応性化合物と、放射
線露光により酸を発生する酸発生剤とを含むレジスト材
料を被処理基板上に塗布し、 前記被処理基板上のレジスト膜を前記酸発生剤からの酸
の発生を惹起し得る放射線に選択的に露光し、そして露
光後のレジスト膜のポストベーク後、前記露光工程にお
いて形成された潜像を現像すること、を含んでなること
を特徴とするレジストパターンの形成方法。12. An alicyclic hydrocarbon group-containing moiety represented by any of the following formulas (I) to (VI): (In the above formula, R I represents a linear or branched alkyl group having 1 to 4 carbon atoms, which may be substituted or unsubstituted, and Z is Represents a plurality of atoms necessary to complete an alicyclic hydrocarbon group) (In the above formula, R II may be the same or different and is a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms or an alicyclic alicyclic hydrocarbon group. Provided that at least one R II is an alicyclic hydrocarbon group. (In the above formula, R II is the same as the above definition.) (In the above formula, R III may be the same or different and represents a proton, a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms or an alicyclic hydrocarbon group. Provided that at least one of R III is an alicyclic hydrocarbon group, and in the formula, at least one of two R III bonded to a non-double bond carbon atom is 1 to 4 A substituted or unsubstituted linear or branched alkyl group having a carbon atom of or an alicyclic hydrocarbon group) (In the above formula, R II is the same as the above definition.) (In the above formula, R I and Z are the same as defined above.)
An acid-sensitive compound having a structural unit having an alkali-soluble group protected by and having the alkali-soluble group eliminated by an acid to make the compound alkali-soluble, and an acid generator capable of generating an acid upon exposure to radiation. A resist material containing a is coated on a substrate to be processed, the resist film on the substrate to be processed is selectively exposed to radiation capable of causing generation of an acid from the acid generator, and the resist film after exposure is A method of forming a resist pattern, comprising: developing the latent image formed in the exposure step after post-baking.
が、カルボン酸基、スルホン酸基、アミド基、イミド基
及びフェノール基からなる群から選ばれた一員であるこ
とを特徴とする、請求項12に記載のパターン形成方
法。13. The alkali-soluble group of the resist material is one member selected from the group consisting of a carboxylic acid group, a sulfonic acid group, an amide group, an imide group and a phenol group. The described pattern forming method.
の脂環式炭化水素基が、複数個の環構造を有するかもし
くは縮合環を有していることを特徴とする、請求項12
又は13に記載のパターン形成方法。14. The alicyclic hydrocarbon group of the alkali-soluble group of the resist material has a plurality of ring structures or has a condensed ring.
Or the pattern forming method as described in 13 above.
の脂環式炭化水素基が、下記の群: (1)アダマンタン及びその誘導体 (2)ノルボルナン及びその誘導体 (3)パーヒドロアントラセン及びその誘導体 (4)パーヒドロナフタレン及びその誘導体 (5)トリシクロ〔5.2.1.02,6 〕デカン及びそ
の誘導体 (6)ビシクロヘキサン及びその誘導体 (7)スピロ〔4,4〕ノナン及びその誘導体 (8)スピロ〔4,5〕デカン及びその誘導体 から選ばれた一員であることを特徴とする、請求項12
又は13に記載のパターン形成方法。15. The alicyclic hydrocarbon group of an alkali-soluble group of the resist material has the following groups: (1) adamantane and its derivative (2) norbornane and its derivative (3) perhydroanthracene and its derivative (4) ) Perhydronaphthalene and its derivatives (5) Tricyclo [5.2.1.0 2,6 ] decane and its derivatives (6) Bicyclohexane and its derivatives (7) Spiro [4,4] nonane and its derivatives (8) 13. A member selected from spiro [4,5] decane and its derivatives.
Or the pattern forming method as described in 13 above.
が、前記構造単位を繰り返し単位として含む重合体又は
共重合体であることを特徴とする、請求項12〜15の
いずれか1項に記載のパターン形成方法。16. The acid sensitive compound of the resist material is a polymer or copolymer containing the structural unit as a repeating unit, according to claim 12. Pattern formation method.
を繰り返し単位として含む共重合体であり、該共重合体
の残りの繰り返し単位が、アルカリ可溶性基を側鎖に有
する繰り返し単位及び(又は)前記酸発生剤から生じる
酸により脱離可能な追加の保護されたアルカリ可溶性基
を側鎖に有する繰り返し単位を含むことを特徴とする、
請求項16に記載のパターン形成方法。17. The acid-sensitive compound is a copolymer containing the structural unit as a repeating unit, and the remaining repeating units of the copolymer have a repeating unit having an alkali-soluble group in a side chain and (or ) A repeating unit having an additional protected alkali-soluble group capable of leaving by an acid generated from the acid generator in a side chain,
The pattern forming method according to claim 16.
(XV)により表される構造単位: 【化22】 【化23】 (上式において、Rは、同一もしくは異なっていてもよ
く、水素、ハロゲン又は1〜4個の炭素原子を有する置
換もしくは非置換の直鎖もしくは分岐鎖のアルキル基を
表し、 RI は、1〜4個の炭素原子を有する直鎖もしくは分岐
鎖のアルキル基を表し、置換もしくは非置換のいずれで
あってもよく、 Aは、酸により脱離可能な保護基を表し、そしてZは、
記載の炭素原子とともに脂環式炭化水素基を完成するの
に必要な複数個の原子を表す)を含むことを特徴とす
る、請求項17に記載のパターン形成方法。18. The structural unit represented by the following formula (XIV) or (XV): Embedded image (In the above formulas, R may be the same or different and represents hydrogen, halogen or a substituted or unsubstituted linear or branched alkyl group having 1 to 4 carbon atoms, and R I is 1 Represents a linear or branched alkyl group having 4 to 4 carbon atoms, which may be substituted or unsubstituted, A represents an acid-eliminating protecting group, and Z represents
18. The pattern forming method according to claim 17, further comprising a plurality of atoms necessary for completing an alicyclic hydrocarbon group together with the described carbon atom.
下記の群: (1)アダマンタン及びその誘導体 (2)ノルボルナン及びその誘導体 (3)パーヒドロアントラセン及びその誘導体 (4)パーヒドロナフタレン及びその誘導体 (5)トリシクロ〔5.2.1.02,6 〕デカン及びそ
の誘導体 (6)ビシクロヘキサン及びその誘導体 (7)スピロ〔4,4〕ノナン及びその誘導体 (8)スピロ〔4,5〕デカン及びその誘導体 から選ばれた一員であることを特徴とする、請求項18
に記載のパターン形成方法。19. The alicyclic hydrocarbon group of the copolymer is
The following groups: (1) adamantane and its derivatives (2) norbornane and its derivatives (3) perhydroanthracene and its derivatives (4) perhydronaphthalene and its derivatives (5) tricyclo [5.2.1.0 2, 6 ] Decane and its derivatives (6) Bicyclohexane and its derivatives (7) Spiro [4,5] nonane and its derivatives (8) Spiro [4,5] decane and its derivatives Claim 18
4. The pattern forming method according to 1.
非重合化合物であり、アルカリ可溶性の重合体又は共重
合体がこの化合物に併用されることを特徴とする、請求
項12〜15のいずれか1項に記載のパターン形成方
法。20. The acid-sensitive compound of the resist material is a non-polymerizable compound, and an alkali-soluble polymer or copolymer is used in combination with this compound. The method for forming a pattern according to item 1.
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KR1019960024415A KR100206664B1 (en) | 1995-06-28 | 1996-06-27 | Chemically amplified resist composition and method for forming resist pattern |
US08/673,739 US6013416A (en) | 1995-06-28 | 1996-06-27 | Chemically amplified resist compositions and process for the formation of resist patterns |
DE19626003A DE19626003C2 (en) | 1995-06-28 | 1996-06-28 | Chemically amplified resist compositions and methods of making resist patterns |
US08/896,833 US5968713A (en) | 1995-06-28 | 1997-07-18 | Chemically amplified resist compositions and process for the formation of resist patterns |
US08/969,368 US6200725B1 (en) | 1995-06-28 | 1997-11-28 | Chemically amplified resist compositions and process for the formation of resist patterns |
US09/739,259 US6329125B2 (en) | 1995-06-28 | 2000-12-19 | Chemically amplified resist compositions and process for the formation of resist patterns |
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