TWI759450B - Etching solution, etching method, and manufacturing method of display device - Google Patents
Etching solution, etching method, and manufacturing method of display device Download PDFInfo
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Abstract
本發明提供抑制了對IGZO造成的損壞之蝕刻液。本發明之蝕刻液係含有羥基乙烷二膦酸(A)、膦酸(B)、過氧化氫(C)、硝酸(D)、氟化合物(E)、唑(F)及鹼(G)之蝕刻液,其特徵為:該膦酸(B)含有選自由二伸乙三胺五亞甲基膦酸、N,N,N’,N’-乙二胺肆亞甲基膦酸及胺基三亞甲基膦酸構成之群組中之1種以上,該羥基乙烷二膦酸(A)之比例為0.01~0.1質量%之範圍,該膦酸(B)之比例為0.003~0.04質量%之範圍。 The present invention provides an etching solution in which damage to IGZO is suppressed. The etching solution of the present invention contains hydroxyethanediphosphonic acid (A), phosphonic acid (B), hydrogen peroxide (C), nitric acid (D), fluorine compound (E), azole (F) and alkali (G) The etching solution is characterized in that: the phosphonic acid (B) contains diethylenetriamine pentamethylene phosphonic acid, N,N,N',N'-ethylenediamine tetramethylenephosphonic acid and amine One or more of the group consisting of oxytrimethylene phosphonic acid, the ratio of the hydroxyethane diphosphonic acid (A) is in the range of 0.01~0.1 mass %, and the ratio of the phosphonic acid (B) is 0.003~0.04 mass % % range.
Description
本發明有關半導體技術,尤其是關於IGZO之保護液及蝕刻液。 The present invention relates to semiconductor technology, especially to the protective solution and etching solution of IGZO.
已有人探討銦鎵鋅氧化物(IGZO),其作為氧化物半導體材料係為有效的材料。但是IGZO容易被酸或鹼蝕刻,故已知有如下問題:使用這些蝕刻液來形成源極-汲極配線時,為基底之IGZO會被腐蝕。 Indium gallium zinc oxide (IGZO) has been studied as an effective material as an oxide semiconductor material system. However, since IGZO is easily etched by acid or alkali, it is known that, when source-drain wirings are formed using these etchants, the IGZO serving as the base is corroded.
為了克服該問題,以往係採用在IGZO上形成保護層後,再形成源極-汲極配線之蝕刻阻擋(etch stopped)型結構(參照圖1),但製造變得繁雜,最後的結果導致成本的增加。於是,為了採用不需要保護層之背通道蝕刻(back channel etch)型結構(參照圖2),冀望有能抑制對IGZO造成的損壞而蝕刻各種配線材料之蝕刻液(參照非專利文獻1)。 In order to overcome this problem, in the past, after forming a protective layer on IGZO, an etch stop type structure (refer to FIG. 1 ) was used to form the source-drain wiring, but the manufacturing became complicated, resulting in cost. increase. Therefore, in order to adopt a back channel etch type structure that does not require a protective layer (see FIG. 2 ), an etchant capable of etching various wiring materials while suppressing damage to IGZO is desired (see Non-Patent Document 1).
又,近年如以4K及8K面板為代表般,面板的高解析度化正急速進展。面板的高解析度化若進展的話,則用以驅動像素之配線圖案會變得密集,為了減少來自背光源所照射的光之損失,必須將配線寬加工成較細。另一方面,為了確保配線中流通的電流量,需要能在獲取配線截面積方面較佳的形狀之配線加工。亦即,冀望能將配線的錐體角(taper angle)加工得較高之蝕刻液。 In addition, in recent years, as represented by 4K and 8K panels, the resolution of panels is rapidly progressing. As the resolution of the panel progresses, the wiring patterns for driving the pixels will become denser, and in order to reduce the loss of light irradiated from the backlight, the wiring width must be made thinner. On the other hand, in order to secure the amount of current flowing through the wiring, a wiring process capable of obtaining a suitable shape in terms of the cross-sectional area of the wiring is required. That is, an etchant that can process the taper angle of the wiring to be higher is desired.
目前,就抑制對IGZO造成的損壞的蝕刻液而言,已知有日本特開2016-11342號公報(專利文獻1)所記載之以低pH為特徵的藥液,但仍無法達成充分的IGZO之抗腐蝕性、加工性。 As an etching solution for suppressing damage to IGZO, a chemical solution characterized by low pH as described in JP 2016-11342 A (Patent Document 1) is known, but sufficient IGZO has not been achieved yet. Corrosion resistance and workability.
[專利文獻1]日本特開2016-11342號公報 [Patent Document 1] Japanese Patent Laid-Open No. 2016-11342
[非專利文獻1]神戶製鋼技報Vol.65,No.2,Sep.2015,森田晋也等「BCE型TFT對應氧化物半導體材料」 [Non-Patent Document 1] Kobe Steel Technical Report Vol.65, No.2, Sep.2015, "Oxide semiconductor material for BCE type TFT" by Shinya Morita et al.
在如此的狀況下,冀望提供一種蝕刻液,能邊抑制對IGZO造成的損壞,邊對配線材料進行蝕刻。 Under such circumstances, it is desired to provide an etchant capable of etching a wiring material while suppressing damage to IGZO.
本發明係如下所述: The present invention is as follows:
[1]一種蝕刻液,含有羥基乙烷二膦酸(A)、膦酸(B)、過氧化氫(C)、硝酸(D)、氟化合物(E)、唑(F)及鹼(G),前述膦酸(B)含有選自由二伸乙三胺五亞甲基膦酸、N,N,N’,N’-乙二胺肆亞甲基膦酸及胺基三亞甲基膦酸構成之群組中之1種以上, 前述羥基乙烷二膦酸(A)之比例為0.01~0.1質量%之範圍,前述膦酸(B)之比例為0.003~0.04質量%之範圍。 [1] An etching solution comprising hydroxyethanediphosphonic acid (A), phosphonic acid (B), hydrogen peroxide (C), nitric acid (D), fluorine compound (E), azole (F) and base (G) ), the aforementioned phosphonic acid (B) contains ethylene triamine pentamethylene phosphonic acid, N,N,N',N'-ethylenediamine tetramethylenephosphonic acid and aminotrimethylenephosphonic acid 1 or more of the formed groups, The ratio of the said hydroxyethane diphosphonic acid (A) is the range of 0.01-0.1 mass %, and the ratio of the said phosphonic acid (B) is the range of 0.003-0.04 mass %.
[2]如[1]所記載之蝕刻液,其中,前述膦酸(B)為二伸乙三胺五亞甲基膦酸。 [2] The etching solution according to [1], wherein the phosphonic acid (B) is ethylenetriaminepentamethylenephosphonic acid.
[3]如[1]或[2]所記載之蝕刻液,其中,前述氟化合物(E)為氟化銨或酸式氟化銨。 [3] The etching solution according to [1] or [2], wherein the fluorine compound (E) is ammonium fluoride or acid ammonium fluoride.
根據本發明之理想態樣,藉由使用本發明之蝕刻液,可防止IGZO受到酸及鹼腐蝕,不需要往IGZO上形成保護層,故可大幅減少製造成本。因此,能製得在蝕刻步驟中防止腐蝕IGZO同時具有高錐體角之配線結構之良好的基板。尤其是在IGZO上具有包含銅層及鈦層之多層薄膜的結構,能進行特別理想的蝕刻所為之加工。 According to an ideal aspect of the present invention, by using the etching solution of the present invention, the IGZO can be prevented from being corroded by acid and alkali, and it is not necessary to form a protective layer on the IGZO, so that the manufacturing cost can be greatly reduced. Therefore, a good substrate with a wiring structure having a high taper angle while preventing corrosion of IGZO in the etching step can be obtained. In particular, on IGZO, a structure having a multilayer thin film including a copper layer and a titanium layer can be processed particularly ideally by etching.
1:光阻層 1: photoresist layer
2:配線層 2: wiring layer
3:阻隔層 3: Barrier layer
4:IGZO層 4: IGZO layer
5:錐體角 5: cone angle
a:頂部CD損失(a×2) a: Top CD loss (a×2)
b:底部CD損失(b×2) b: Bottom CD loss (b×2)
c:曳尾(c×2) c: trailing tail (c×2)
[圖1]係於IGZO上設有保護層之以往的蝕刻阻擋型結構之TFT示意圖之一例。 [FIG. 1] It is an example of the schematic diagram of the TFT of the conventional etching stop type structure provided with the protective layer on IGZO.
[圖2]係未設置保護層之背通道蝕刻型結構之TFT示意圖之一例。 FIG. 2 is an example of a schematic diagram of a TFT with a back-channel etched structure without a protective layer.
[圖3]係使用了本發明的蝕刻液時之配線剖面的示意圖之一例。 3] It is an example of the schematic diagram of the wiring cross section when the etching liquid of this invention is used.
[圖4]係使用了實施例或比較例的蝕刻液時之IGZO的剖面觀察之一例。 FIG. 4 is an example of cross-sectional observation of IGZO when the etching solution of the example or the comparative example is used.
[圖5]係使用了實施例或比較例的蝕刻液時之IGZO的表面觀察之一例。 FIG. 5 is an example of surface observation of IGZO when the etching solution of the example or the comparative example was used.
本發明之蝕刻液藉由含有羥基乙烷二膦酸(A)及特定的膦酸(B),可具有對於IGZO之抗腐蝕性。又,藉由更含有過氧化氫(C)、硝酸(D)、氟化合物(E)、唑(F)及鹼(G),可獲得具有對於IGZO之抗腐蝕性,同時能對配線材料進行蝕刻之組成物。 The etching solution of the present invention can have corrosion resistance to IGZO by containing hydroxyethanediphosphonic acid (A) and specific phosphonic acid (B). In addition, by further containing hydrogen peroxide (C), nitric acid (D), fluorine compound (E), azole (F) and alkali (G), corrosion resistance to IGZO can be obtained, and at the same time, the wiring material can be improved. Etched composition.
以下,針對本發明之蝕刻液的各成分進行詳細地說明。 Hereinafter, each component of the etching liquid of this invention is demonstrated in detail.
羥基乙烷二膦酸(A)係式(1)表示之化合物。 The hydroxyethanediphosphonic acid (A) is a compound represented by the formula (1).
HEDP(A)在蝕刻液中之比例為0.01~0.1質量%之範圍,宜為0.03~0.08質量%之範圍。藉由使HEDP(A)之濃度範圍在此範圍內,可賦予較高之IGZO的抗腐蝕性能,且可防止IGZO表面之粗糙。 The ratio of HEDP (A) in the etching solution is in the range of 0.01 to 0.1 mass %, preferably in the range of 0.03 to 0.08 mass %. By making the concentration range of HEDP (A) within this range, higher corrosion resistance of IGZO can be imparted, and roughening of the surface of IGZO can be prevented.
藉由和HEDP(A)一起使用膦酸(B),可賦予較高之IGZO的抗腐蝕性,同時能將配線形狀加工成高錐體角。 By using phosphonic acid (B) together with HEDP (A), higher corrosion resistance of IGZO can be imparted, and the wiring shape can be processed into a high taper angle.
本發明中的膦酸(B)係選自由二伸乙三胺五亞甲基膦酸、N,N,N’,N’-乙二胺肆亞甲基膦酸及胺基三亞甲基膦酸構成之群組中之1種以上的膦酸。它們之中,N,N,N’,N’-乙二胺肆亞甲基膦酸對IGZO之抗腐蝕性高,故較理想。 The phosphonic acid (B) in the present invention is selected from the group consisting of diethylenetriaminepentamethylenephosphonic acid, N,N,N',N'-ethylenediaminetetramethylenephosphonic acid and aminotrimethylenephosphine One or more phosphonic acids in the group consisting of acids. Among them, N,N,N',N'-ethylenediamine-methylenephosphonic acid has high corrosion resistance to IGZO, so it is preferable.
膦酸(B)在蝕刻液中之比例為0.003~0.04質量%之範圍,宜為0.01~0.03質量%,為0.015~0.03質量%之範圍更佳。藉由使膦酸(B)之濃度範圍在此範圍內,可達成較高之IGZO的抗腐蝕性能。 The ratio of the phosphonic acid (B) in the etching solution is in the range of 0.003 to 0.04 mass %, preferably 0.01 to 0.03 mass %, and more preferably in the range of 0.015 to 0.03 mass %. By making the concentration range of phosphonic acid (B) within this range, higher corrosion resistance of IGZO can be achieved.
過氧化氫(C)係作為氧化劑而具有將銅氧化的功能。 Hydrogen peroxide (C) has a function of oxidizing copper as an oxidizing agent.
過氧化氫(C)在蝕刻液中之比例宜為4.0~8.0質量%之範圍,為4.5~7.5質量%更佳,為5.0~6.5質量%之範圍特佳。藉由使過氧化氫(C)之濃度範圍在此範圍內,可適當地實施蝕刻速度之確保與配線的局部腐蝕之抑制。 The ratio of hydrogen peroxide (C) in the etching solution is preferably in the range of 4.0 to 8.0 mass %, more preferably in the range of 4.5 to 7.5 mass %, and particularly preferably in the range of 5.0 to 6.5 mass %. By setting the concentration range of the hydrogen peroxide (C) within this range, the securing of the etching rate and the suppression of the local corrosion of the wiring can be appropriately performed.
硝酸(D)具有使已利用過氧化氫氧化後的銅溶解之效果等。 The nitric acid (D) has an effect of dissolving copper after hydrogen peroxide has been used, and the like.
硝酸(D)在蝕刻液中之比例宜為0.8~7.0質量%之範圍,為1.5~6.5質量%更佳,為2.0~6.0質量%之範圍特佳。藉由使硝酸(D)之濃度範圍在此範圍內,可確保良好的蝕刻速率,且可獲得良好的配線形狀。 The ratio of nitric acid (D) in the etching solution is preferably in the range of 0.8 to 7.0 mass %, more preferably in the range of 1.5 to 6.5 mass %, and particularly preferably in the range of 2.0 to 6.0 mass %. By making the concentration range of nitric acid (D) within this range, a favorable etching rate can be ensured, and a favorable wiring shape can be obtained.
氟化合物(E)具有蝕刻由鈦系金屬構成的阻隔層之功能。 The fluorine compound (E) has a function of etching a barrier layer made of a titanium-based metal.
氟化合物(E)之種類若為會產生氟離子者則無限制。就具體例而言,可列舉:氫氟酸、氟化銨及酸式氟化銨,它們之中,由於氟化銨及酸式氟化銨為低毒性,故較理想。氟化合物(E)可使用1種,也可將2種以上合併使用。 The type of the fluorine compound (E) is not limited as long as it generates fluoride ions. Specific examples include hydrofluoric acid, ammonium fluoride, and acid ammonium fluoride, and among them, ammonium fluoride and acid ammonium fluoride are preferable because they have low toxicity. The fluorine compound (E) may be used alone or in combination of two or more.
氟化合物(E)在蝕刻液中之比例宜為0.2~0.8質量%之範圍,為0.2~0.6質量%更佳,為0.2~0.5質量%之範圍特佳。藉由使氟化合物(E)之濃度範圍在此範圍內,可獲得對由鈦系金屬構成的阻隔層之良好的蝕刻速度。 The ratio of the fluorine compound (E) in the etching solution is preferably in the range of 0.2 to 0.8 mass %, more preferably in the range of 0.2 to 0.6 mass %, and particularly preferably in the range of 0.2 to 0.5 mass %. By setting the concentration range of the fluorine compound (E) within this range, a favorable etching rate for the barrier layer made of a titanium-based metal can be obtained.
唑(F)係為了利用pH來調整蝕刻速度而使用。就唑(F)之具體例而言,可列舉:1,2,4-三唑、1H-苯并三唑、5-甲基-1H-苯并三唑、3-胺基-1H-三唑等三唑類;1H-四唑、5-甲基-1H-四唑、5-苯基-1H-四唑、5-胺基-1H-四唑等四唑類;1,3-噻唑、4-甲基噻唑等噻唑類等。它們之中,宜為四唑類,其中,就在溶液中不會和銅離子形成不溶性的鹽之觀點,宜為5-胺基-1H-四唑。唑(F)可使用1種,也可將2種以上合併使用。 The azole (F) is used to adjust the etching rate by pH. Specific examples of the azole (F) include 1,2,4-triazole, 1H-benzotriazole, 5-methyl-1H-benzotriazole, and 3-amino-1H-triazole azoles and other triazoles; 1H-tetrazole, 5-methyl-1H-tetrazole, 5-phenyl-1H-tetrazole, 5-amino-1H-tetrazole and other tetrazoles; 1,3-thiazole , 4-methylthiazole and other thiazoles. Among them, tetrazoles are preferred, and among them, 5-amino-1H-tetrazole is preferred from the viewpoint of not forming an insoluble salt with copper ions in a solution. The azoles (F) may be used alone or in combination of two or more.
唑(F)在蝕刻液中之比例宜為0.05~0.35質量%之範圍,為0.05~0.30質量%更佳,為0.08~0.25質量%特佳。藉由使唑(F)之濃度範圍在此範圍內,能適當地調整蝕刻速度,可獲得良好的配線形狀。 The ratio of the azole (F) in the etching solution is preferably in the range of 0.05 to 0.35 mass %, more preferably 0.05 to 0.30 mass %, and particularly preferably 0.08 to 0.25 mass %. By making the concentration range of the azole (F) within this range, the etching rate can be appropriately adjusted, and a favorable wiring shape can be obtained.
鹼(G)係為了利用pH來調整蝕刻速度而使用。鹼(G)若為通常使用來製成蝕刻液之種類則無限制,可列舉例如:氨、氫氧化鉀、氫氧化四級銨及胺化合物。 The alkali (G) is used in order to adjust the etching rate by pH. The alkali (G) is not limited as long as it is a kind that is usually used to prepare an etching solution, and examples thereof include ammonia, potassium hydroxide, quaternary ammonium hydroxide, and an amine compound.
就胺化合物而言,可列舉:乙胺、異丙胺等烷基胺類;以N-丙醇胺、N-甲基乙醇胺為代表之烷醇胺類;以乙二胺為代表之二胺。它們之中,就不會使過氧化氫之安定性惡化的觀點,宜為氫氧化四級銨、N-丙醇胺及N-丁基乙醇胺。鹼(G)可使用1種,亦可將2種以上合併使用。 The amine compound includes alkylamines such as ethylamine and isopropylamine; alkanolamines typified by N-propanolamine and N-methylethanolamine; and diamines typified by ethylenediamine. Among them, quaternary ammonium hydroxide, N-propanolamine and N-butylethanolamine are preferable from the viewpoint of not deteriorating the stability of hydrogen peroxide. The base (G) may be used alone or in combination of two or more.
鹼(G)在蝕刻液中之比例宜為0.6~10質量%之範圍,為1.0~9.0質量%更佳,為2.0~8.0質量%之範圍特佳。藉由使濃度範圍在此範圍內,可適當地調節蝕刻速度。 The ratio of the alkali (G) in the etching solution is preferably in the range of 0.6 to 10 mass %, more preferably in the range of 1.0 to 9.0 mass %, and particularly preferably in the range of 2.0 to 8.0 mass %. By making the concentration range within this range, the etching rate can be appropriately adjusted.
本發明之蝕刻液中,在不損及本發明目的之範圍內,可含有自以往即用在蝕刻液中之添加劑、過氧化氫安定劑、界面活性劑、著色劑、消泡劑等。 The etching solution of the present invention may contain additives, hydrogen peroxide stabilizers, surfactants, colorants, defoaming agents, etc., which have been conventionally used in etching solutions, within the range that does not impair the purpose of the present invention.
本發明之蝕刻液係藉由在HEDP(A)、膦酸(B)、過氧化氫(C)、硝酸(D)、氟化合物(E)、唑(F)、鹼(G)及因應需要之其他成分中,添加水(理想為超純水)後攪拌至均勻而製得。 The etching solution of the present invention is prepared by mixing HEDP (A), phosphonic acid (B), hydrogen peroxide (C), nitric acid (D), fluorine compound (E), azole (F), alkali (G) and according to needs To other components, add water (ideally ultrapure water) and stir until uniform.
組成液之pH的範圍並無特別限制,通常為1.5~2.8,宜為1.8~2.5。藉由使其在此範圍內,可對於IGZO適當地抗腐蝕,同時對配線材料進行蝕刻。 The range of pH of the composition liquid is not particularly limited, but is usually 1.5 to 2.8, preferably 1.8 to 2.5. By making it within this range, corrosion resistance to IGZO can be suitably performed, and the wiring material can be etched at the same time.
藉由使本發明之蝕刻液與對象物接觸,可將對象物予以蝕刻。 The object can be etched by bringing the etchant of the present invention into contact with the object.
使本發明之蝕刻液接觸對象物之方法並無特別限制,可採用例如:利用滴加(單片式旋轉處理)或噴霧等形式使其與對象物接觸的方法、或使對象物浸漬於本發明之蝕刻液中之方法。 The method for bringing the etching solution of the present invention into contact with the object is not particularly limited, and for example, a method of bringing the etchant of the present invention into contact with the object in the form of dropping (single-chip spin treatment) or spraying, or immersing the object in the present invention can be adopted. Invention of the method in the etching solution.
使用本發明之蝕刻液的溫度範圍通常為10~70℃,宜為20~50℃。使用蝕刻液的時間通常為0.2~60分鐘。就蝕刻後之沖洗液而言,可使用有機溶劑與水之中的任意者。 The temperature range of using the etching solution of the present invention is usually 10 to 70°C, preferably 20 to 50°C. The time for using the etching solution is usually 0.2 to 60 minutes. As the rinse solution after etching, any one of an organic solvent and water can be used.
作為本發明之蝕刻液對象之基板宜具有IGZO,IGZO若為含有銦、鎵、鋅及氧而構成的半導體,則無特別限制。上述氧化物可為非晶質結構,亦可具有結晶性。 The substrate which is the subject of the etching solution of the present invention preferably has IGZO, and IGZO is not particularly limited as long as it is a semiconductor composed of indium, gallium, zinc, and oxygen. The above-mentioned oxide may have an amorphous structure or may have crystallinity.
將IGZO使用作為例如薄膜電晶體(TFT:Thin Film Transistor)等電子元件時,IGZO係使用濺鍍法等成膜處理而形成於玻璃等基板上。然後,藉由以光阻等作為遮罩進行蝕刻來形成電極圖案。再於其上使用濺鍍法等成膜處理形成銅(Cu)及鈦(Ti)等,然後,藉由以光阻等作為遮罩進行蝕刻來形成源極-汲極電極。 For example, when IGZO is used as an electronic element such as a thin film transistor (TFT: Thin Film Transistor), IGZO is formed on a substrate such as glass using a film formation process such as sputtering. Then, electrode patterns are formed by etching using a photoresist or the like as a mask. Then, copper (Cu), titanium (Ti), etc. are formed thereon by using a film-forming process such as sputtering, and then, source-drain electrodes are formed by etching using a photoresist or the like as a mask.
圖3係使用了本發明之蝕刻液時的配線剖面之示意圖之一例。如圖3所示之於IGZO層(4)上介隔含有鈦之鈦層等阻隔層(3),具有由含有銅之銅層構成的配線層(2)之具有多層薄膜的結構,可理想地使用在平板顯示器等顯示裝置等之配線,且本發明之蝕刻液的性能會特別有效地發揮。根據本發明之理想的態樣,藉由以光阻層(1)作為遮罩,使用本發明之蝕刻液來蝕刻此多層薄膜,可形成期望的配線結構。另外,圖3中,從光阻層(1)端部到與光阻層(1)相接觸之配線層(2)端部為止的距離(a)之2倍稱為頂部CD損失(a×2),從光阻層(1)端部到與設置於配線(2)下之阻隔層(3)相接觸之配線層(2)端部為止的距離(b)之2倍稱為底部CD損失(b×2)。又,從配線層(2)端部到阻隔層(3)之端部為止的距離(c)之2倍(c×2)稱為曳尾(tailing)。又,配線層(2)端部之蝕刻面與下層之IGZO層(4)所成的角度稱為錐體角(5)。 FIG. 3 is an example of a schematic diagram of a wiring cross section when the etching solution of the present invention is used. As shown in FIG. 3, a barrier layer (3), such as a titanium layer containing titanium, is interposed on the IGZO layer (4), and a wiring layer (2) composed of a copper layer containing copper has a structure with a multilayer thin film, which is ideal. The performance of the etching solution of the present invention is particularly effectively used in the wiring of display devices such as flat panel displays. According to an ideal aspect of the present invention, a desired wiring structure can be formed by using the photoresist layer (1) as a mask and etching the multilayer thin film using the etching solution of the present invention. In addition, in FIG. 3, twice the distance (a) from the end of the photoresist layer (1) to the end of the wiring layer (2) in contact with the photoresist layer (1) is referred to as the top CD loss (a× 2), 2 times the distance (b) from the end of the photoresist layer (1) to the end of the wiring layer (2) in contact with the barrier layer (3) disposed under the wiring (2) is called the bottom CD loss (b×2). Moreover, twice (c×2) of the distance (c) from the end of the wiring layer (2) to the end of the barrier layer (3) is called tailing. Moreover, the angle formed by the etching surface of the edge part of the wiring layer (2) and the IGZO layer (4) of the lower layer is called a taper angle (5).
以下,利用實施例具體地說明本發明,但只要能發揮本發明之效果,則可適當變化實施形態。 Hereinafter, the present invention will be specifically described with reference to examples, but the embodiments may be appropriately changed as long as the effects of the present invention can be exhibited.
另外,只要沒有特別指定,則%意指質量%。 In addition, unless otherwise specified, % means mass %.
<IGZO之蝕刻速率及表面狀態評價用之基板(1)> <Substrate (1) for Etching Rate and Surface Condition Evaluation of IGZO>
利用濺鍍法在玻璃基板上以膜厚1000Å(100nm)之條件形成銦(In)、鎵(Ga)、鋅(Zn)及氧(O)之元素比為1:1:1:4之IGZO(100mm×100mm×1mm)。 The elemental ratio of indium (In), gallium (Ga), zinc (Zn) and oxygen (O) is 1:1:1:4 IGZO is formed on a glass substrate by sputtering with a film thickness of 1000Å (100nm). (100mm×100mm×1mm).
<對於包含銅層及鈦層之多層薄膜之蝕刻性能評價用之基板(2)> <Substrate (2) for Etching Performance Evaluation of Multilayer Thin Films Containing Copper Layer and Titanium Layer>
以厚度25nm之條件將鈦濺鍍於玻璃基板而形成鈦層,然後以600nm之厚度濺鍍銅,疊層配線材料之銅層。然後,塗佈光阻,將圖案遮罩予以曝光轉印後,進行顯影形成配線圖案,於玻璃基板上製作包含銅層及鈦層之多層薄膜(100mm×100mm×1mm)。 Titanium was sputtered on a glass substrate with a thickness of 25 nm to form a titanium layer, and then copper was sputtered with a thickness of 600 nm to laminate the copper layer of the wiring material. Then, a photoresist was coated, the pattern mask was exposed and transferred, and then developed to form a wiring pattern, and a multilayer film (100mm×100mm×1mm) including a copper layer and a titanium layer was fabricated on the glass substrate.
調製由表1或2所記載之(C)、(D)、(E)、(F)及(G)成分濃度構成的組成物後,各別添加銅粉末6000ppm及鈦粉末150ppm,進行攪拌直到金屬溶解。確認金屬溶解後,以預定濃度添加(A)及(B)成分,製成蝕刻液。藉由將基板(1)於35℃靜置浸漬於各別的蝕刻液中20秒來實施蝕刻。其後進行水洗,再使用氮氣使其乾燥。 After preparing a composition having the concentrations of (C), (D), (E), (F), and (G) components described in Table 1 or 2, 6000 ppm of copper powder and 150 ppm of titanium powder were added, respectively, and the mixture was stirred until Metal dissolves. After confirming that the metal was dissolved, components (A) and (B) were added at predetermined concentrations to prepare an etching solution. The etching was performed by immersing the substrate ( 1 ) at 35° C. for 20 seconds in the respective etching solutions. After that, it was washed with water and dried with nitrogen gas.
利用n & k Analyzer 1280(n & k Technology Inc.)測定蝕刻後之膜厚,再藉由將其膜厚差除以蝕刻時間來算出蝕刻速率,並利用如下基準進行判定。 The film thickness after etching was measured by n & k Analyzer 1280 (n & k Technology Inc.), and the etching rate was calculated by dividing the difference in film thickness by the etching time, and the following criteria were used for determination.
E:蝕刻速率未達5Å/sec E: The etching rate is less than 5Å/sec
G:蝕刻速率5Å/sec以上未達8Å/sec G: The etching rate is more than 5Å/sec and less than 8Å/sec
P:蝕刻速率8Å/sec以上未達10Å/sec P: The etching rate is more than 8Å/sec and less than 10Å/sec
B:蝕刻速率10Å/sec以上 B: Etching rate of 10Å/sec or more
將E、G及P評為合格。 E, G and P were rated as passable.
將已測定IGZO之蝕刻速率後的IGZO薄膜進行裁切,使用掃描式電子顯微鏡(型號:S5000H型,日立製作所(股)製)以倍率50000倍(加速電壓2kV,加速電流10μA)觀察表面的粗糙狀況,並利用如下基準進行判定。 The IGZO thin film after the etching rate of IGZO was measured was cut, and the surface roughness was observed using a scanning electron microscope (model: S5000H, manufactured by Hitachi, Ltd.) at a magnification of 50,000 times (accelerating voltage 2kV, accelerating current 10μA). situation, and use the following criteria to judge.
E:平滑的表面狀態 E: Smooth surface state
G:表面產生輕微粗糙,以掃描式電子顯微鏡觀察IGZO剖面時,凹凸部之差未達25nm,或以掃描式電子顯微鏡觀察IGZO表面時,每單位面積(1200nm×1200nm)之空隙部分的產生數未達20處 G: The surface is slightly rough, and when the IGZO cross section is observed with a scanning electron microscope, the difference between the concave and convex portions is less than 25 nm, or when the IGZO surface is observed with a scanning electron microscope, the number of voids per unit area (1200 nm × 1200 nm) is generated. less than 20
B:表面產生顯著的粗糙、空隙,以掃描式電子顯微鏡觀察IGZO剖面時,凹凸部之差為25nm以上,或以掃描式電子顯微鏡觀察IGZO表面時,每單位面積(1200nm×1200nm)之空隙部分的產生數為20處以上 B: Significant roughness and voids occur on the surface. When the IGZO cross section is observed with a scanning electron microscope, the difference between the concave and convex portions is 25 nm or more, or when the IGZO surface is observed with a scanning electron microscope, the void portion per unit area (1200 nm×1200 nm) The number of occurrences is more than 20
將E及G評為合格。 E and G were rated as passable.
IGZO之剖面觀察之一例如圖4所示,表面觀察之一例如圖5所示。 An example of cross-sectional observation of IGZO is shown in FIG. 4 , and an example of surface observation is shown in FIG. 5 .
調製由表1或2所記載之(C)、(D)、(E)、(F)及(G)成分濃度構成的組成物後,各別添加銅粉末6000ppm、鈦粉末150ppm,進行攪拌直到金屬溶解。確認金屬溶解後,以預定濃度添加(A)及(B)成分,製成蝕刻液。將基板(2)於35℃靜置浸漬於各別的蝕刻液中150秒來實施蝕刻,其後進行水洗,再使用氮氣使其乾燥。 After preparing a composition having the concentrations of (C), (D), (E), (F), and (G) components described in Table 1 or 2, 6000 ppm of copper powder and 150 ppm of titanium powder were added, respectively, and the mixture was stirred until Metal dissolves. After confirming that the metal was dissolved, components (A) and (B) were added at predetermined concentrations to prepare an etching solution. The substrate ( 2 ) was immersed at 35° C. for 150 seconds and immersed in the respective etching solutions to perform etching, then washed with water, and then dried using nitrogen gas.
將利用上述蝕刻方法得到的包含銅層及鈦層之多層薄膜樣本進行裁切,並使用掃描式電子顯微鏡(型號:S5000H型,日立製作所(股)製)以倍率50000倍(加速電壓2kV,加速電流10μA)觀察剖面。 The multi-layer thin film sample comprising the copper layer and the titanium layer obtained by the above-mentioned etching method was cut, and a scanning electron microscope (Model: S5000H, manufactured by Hitachi, Ltd.) was used at a magnification of 50,000 times (acceleration voltage 2kV, accelerated Current 10 μA) to observe the cross section.
基於得到的SEM圖像測定如圖3所示之錐體角5,利用如下基準判定蝕刻後之形狀。
The
錐體角 cone angle
E:60°以上未達70° E: Above 60° and less than 70°
G:50以上未達60° G: 50 or more but less than 60°
B:未達50°或70°以上 B: less than 50° or more than 70°
將E及G評為合格。 E and G were rated as passable.
評價結果如表1及2所示。 The evaluation results are shown in Tables 1 and 2.
另外,表中的成分如下所述。 In addition, the components in the table are as follows.
B1:N,N,N’,N’乙二胺肆亞甲基膦酸 B1: N,N,N',N'ethylenediamine4methylenephosphonic acid
B2:二伸乙三胺五亞甲基膦酸 B2: Diethylenetriamine pentamethylenephosphonic acid
B3:胺基三亞甲基膦酸 B3: amino trimethylene phosphonic acid
B4:磷酸 B4: Phosphoric acid
B5:膦酸 B5: Phosphonic acid
B6:五伸乙八亞甲基膦酸 B6: Pentaethylene octamethylenephosphonic acid
E1:酸式氟化銨 E1: acid ammonium fluoride
F1:5-胺基-1H-四唑 F1: 5-amino-1H-tetrazole
G1:氫氧化四級銨 G1: quaternary ammonium hydroxide
G2:氫氧化鉀 G2: Potassium Hydroxide
G3:N-丁基乙醇胺 G3: N-butylethanolamine
G4:氨 G4: Ammonia
G5:1-胺基-2丙醇 G5: 1-Amino-2-propanol
本發明之蝕刻液可理想地使用於含有IGZO之基板中的配線材料之蝕刻。根據本發明之理想態樣,可製成防止腐蝕IGZO同時具有高錐體角之配線結構的基板。 The etchant of the present invention can be ideally used for etching of wiring materials in substrates containing IGZO. According to an ideal aspect of the present invention, a substrate with a wiring structure having a high taper angle while preventing corrosion of IGZO can be produced.
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