TWI503982B - N-type metal oxide semiconductor (mos) device and manufacturing method thereof - Google Patents
N-type metal oxide semiconductor (mos) device and manufacturing method thereof Download PDFInfo
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本發明係有關一種N型金屬氧化物半導體(metal oxide semiconductor,MOS)元件及其製造方法;特別是指一種利用增加部分P型井區的寬度以增加N型MOS元件的崩潰(breakdown)電壓。The present invention relates to an N-type metal oxide semiconductor (MOS) device and a method of fabricating the same; and more particularly to an increase in the width of a portion of a P-type well region to increase a breakdown voltage of an N-type MOS device.
第1A與1B圖分別顯示一種習知N型金屬氧化物半導體(metal oxide semiconductor,MOS)元件100的剖視示意圖與上視示意圖。如第1A與1B圖所示,N型MOS元件100包含基板11、P型井區12、隔絕區13、本體極14、閘極15、N型源極16、與N型汲極17。其中,隔絕區13定義操作區13a,作為N型MOS元件100操作時主要的作用區。而P型井區12、本體極14的導電型為P型,N型源極16與N型汲極17的導電型為N型。請參閱第1A圖,當N型MOS元件100操作時,需要避免寄生電晶體導通所造成的崩潰。詳言之,如圖中虛線所示意的寄生雙極性接面電晶體(bipolar junction transistor,BJT),其具有基極B、射極E、與集極C。其中,寄生BJT的基極B、射極E、與集極C分別對應N型MOS元件100的P型井區12、N型源極16、與N型汲極17。當基極-射極電壓Vbe高於寄生BJT的阻障(barrier)時,寄生BJT會導通。而基極-射極電壓Vbe相關於基極電阻Rb(未示出,指基極B與射極E間之電阻值,其為本領域技術者所熟知,在此不予贅述),也就是說,基極電阻Rb越大,N型MOS元件100操作時,基極-射極電壓Vbe就越大,越容易發生崩潰。1A and 1B are schematic cross-sectional and top views, respectively, of a conventional N-type metal oxide semiconductor (MOS) device 100. As shown in FIGS. 1A and 1B, the N-type MOS device 100 includes a substrate 11, a P-type well region 12, an isolation region 13, a body electrode 14, a gate 15, an N-type source 16, and an N-type drain 17. Among them, the isolation region 13 defines the operation region 13a as a main action region when the N-type MOS device 100 operates. The conductivity type of the P-type well region 12 and the body pole 14 is P-type, and the conductivity type of the N-type source electrode 16 and the N-type drain electrode 17 is N-type. Referring to FIG. 1A, when the N-type MOS device 100 is operated, it is necessary to avoid the collapse caused by the parasitic transistor conduction. In detail, a parasitic bipolar junction transistor (BJT), as illustrated by the dashed line in the figure, has a base B, an emitter E, and a collector C. The base B, the emitter E, and the collector C of the parasitic BJT correspond to the P-type well region 12, the N-type source electrode 16, and the N-type drain electrode 17 of the N-type MOS device 100, respectively. When the base-emitter voltage Vbe is higher than the barrier of the parasitic BJT, the parasitic BJT will conduct. The base-emitter voltage Vbe is related to the base resistance Rb (not shown, which refers to the resistance value between the base B and the emitter E, which is well known to those skilled in the art and will not be described here), that is, It is said that the larger the base resistance Rb is, the larger the base-emitter voltage Vbe is when the N-type MOS device 100 is operated, and the more likely the collapse occurs.
當N型MOS元件的操作區寬度在尺寸上縮小至5微米以下時,寄生BJT較容易導通,尤其是在溫度升高的狀況下。因此,元件設計者會遭遇一個問題,就是在元件操作區寬度因元件微縮而減少的狀況下,造成寄生BJT的基極電阻Rb增加,而容易導通,進而使崩潰防護電壓因為 寄生BJT的導通而降低,這是因為使寄生BJT導通時的汲極電壓,比一般的累增崩潰(avalanche breakdown)發生時的汲極電壓低所造成的。因此,無法利用降低P型井區的雜質濃度之方法來提高崩潰防護電壓。When the operating region width of the N-type MOS device is reduced in size to less than 5 μm, the parasitic BJT is easier to conduct, especially in the case of an increase in temperature. Therefore, the component designer will encounter a problem that the base resistance Rb of the parasitic BJT is increased and the conduction resistance is easily turned on when the width of the operation area of the component is reduced due to the miniaturization of the component, thereby causing the breakdown protection voltage to be The parasitic BJT is turned on and lowered because the gate voltage when the parasitic BJT is turned on is lower than the threshold voltage at which the avalanche breakdown occurs. Therefore, it is impossible to increase the collapse protection voltage by reducing the impurity concentration of the P-type well region.
相似地,第3A-3B圖分別顯示一種習知N型橫向雙擴散金屬氧化物半導體(lateral double diffused metal oxide semiconductor,LDMOS)元件300的剖視示意圖與上視示意圖。如第3A與3B圖所示,N型LDMOS元件300包含基板31、P型井區32、隔絕區33、本體極34、閘極35、N型源極36、N型汲極37、與N型井區38。其中,隔絕區33定義操作區33a,作為N型LDMOS元件300操作時主要的作用區。而P型井區32、本體極34的導電型為P型,N型源極36、N型汲極37、與N型井區38的導電型為N型。請參閱第3A圖,當N型LDMOS元件300操作時,需要避免寄生BJT導通所造成的崩潰。詳言之,如圖中虛線所示意的寄生雙極性接面電晶體,其具有基極B、射極E、與集極C。其中,寄生BJT的基極B、射極E、與集極C分別對應N型LDMOS元件300的P型井區32、N型源極36、與N型井區38。與N型MOS元件100相似,當N型LDMOS元件的操作區寬度在尺寸上縮小至5微米以下時,相較於累增崩潰,造成寄生BJT導通的汲極電壓較低,使得崩潰防護電壓下降。因此,無法利用降低P型井區的雜質濃度之方法來提高崩潰防護電壓。Similarly, Figures 3A-3B show a schematic cross-sectional view and a top view, respectively, of a conventional N-type lateral double diffused metal oxide semiconductor (LDMOS) device 300. As shown in FIGS. 3A and 3B, the N-type LDMOS device 300 includes a substrate 31, a P-type well region 32, an isolation region 33, a body electrode 34, a gate 35, an N-type source 36, an N-type drain 37, and N. Type well area 38. The isolation region 33 defines an operation region 33a as a main active region when the N-type LDMOS device 300 operates. The conductivity type of the P-type well region 32 and the body pole 34 is P-type, and the conductivity type of the N-type source electrode 36, the N-type drain electrode 37, and the N-type well region 38 is N-type. Referring to FIG. 3A, when the N-type LDMOS device 300 is operated, it is necessary to avoid the collapse caused by the parasitic BJT conduction. In detail, a parasitic bipolar junction transistor, as illustrated by the dashed line in the figure, has a base B, an emitter E, and a collector C. The base B, the emitter E, and the collector C of the parasitic BJT correspond to the P-type well region 32, the N-type source 36, and the N-type well region 38 of the N-type LDMOS device 300, respectively. Similar to the N-type MOS device 100, when the operating region width of the N-type LDMOS device is reduced in size to less than 5 μm, the drain voltage of the parasitic BJT is lower than that of the cumulative collapse, and the breakdown protection voltage is lowered. . Therefore, it is impossible to increase the collapse protection voltage by reducing the impurity concentration of the P-type well region.
有鑑於此,本發明即針對上述先前技術之改善,提出一種N型MOS元件及其製造方法,可避免寄生BJT導通,提高元件的崩潰防護電壓。In view of the above, the present invention is directed to an improvement of the prior art described above, and provides an N-type MOS device and a method of fabricating the same, which can prevent parasitic BJT conduction and improve the breakdown protection voltage of the component.
就其中一觀點言,本發明提供了一種N型金屬氧化物半導體(metal oxide semiconductor,MOS)元件,形成於一基板中,該基板具有一上表面,該N型MOS元件包含:一隔絕區,形成於該上表面上,以定義一操作區;一P型井區,形成於該上表面下;一N型源極,形成於該上表面下;一N型汲極,形成於該上表面下;一閘極,形成於該上表面上,該閘極介於該N型源極與該N型汲極之間;以及一本體極,與該N型源極形成於該閘極同側,且該N型源極介於該本體極與該閘極之間,該本體極用以作為 該P型井區之電性接點;其中,該P型井區具有彼此連接之一第一部分與一第二部分,該第一部分與該源極位於該閘極同側,且該第一部份與該第二部分之間具有一第一接面,該第一接面介於該閘極與該本體極之間,由上視圖視之,該第一部份於該第一接面處之一寬度方向上,兩端皆超過該第二部分至少2微米。In one aspect, the present invention provides an N-type metal oxide semiconductor (MOS) device formed in a substrate having an upper surface, the N-type MOS device comprising: an isolation region, Formed on the upper surface to define an operating region; a P-type well region formed under the upper surface; an N-type source formed under the upper surface; an N-type drain formed on the upper surface a gate formed on the upper surface, the gate being interposed between the N-type source and the N-type drain; and a body pole formed on the same side of the gate as the N-type source And the N-type source is between the body pole and the gate, and the body pole is used as An electrical contact of the P-type well region; wherein the P-type well region has a first portion and a second portion connected to each other, the first portion and the source are located on the same side of the gate, and the first portion Between the second portion and the second portion, the first junction is between the gate and the body, as viewed from a top view, the first portion is at the first junction In one of the width directions, both ends are at least 2 microns beyond the second portion.
就另一觀點言,本發明提供了一種N型金屬氧化物半導體(metal oxide semiconductor,MOS)元件製造方法,包含:提供一基板,且該基板具有一上表面;形成一隔絕區於該上表面上,以定義一操作區;形成一P型井區於該上表面下;形成一閘極於該上表面上;形成一N型源極於該上表面下;形成一N型汲極於該上表面下,其中,該閘極介於該N型源極與該N型汲極之間;以及形成一本體極,該本體極與該N型源極位於該閘極同側,且該N型源極介於該本體極與該閘極之間,該本體極用以作為該P型井區之電性接點;其中,該P型井區具有彼此連接之一第一部分與一第二部分,該第一部分與該源極位於該閘極同側,且該第一部份與該第二部分之間具有一第一接面,該第一接面介於該閘極與該本體極之間,由上視圖視之,該第一部份於該第一接面處之一寬度方向上,兩端皆超過該第二部分至少2微米。In another aspect, the present invention provides a method of fabricating an N-type metal oxide semiconductor (MOS) device, comprising: providing a substrate having an upper surface; forming an isolation region on the upper surface Upper to define an operating region; forming a P-type well region below the upper surface; forming a gate on the upper surface; forming an N-type source under the upper surface; forming an N-type drain a lower surface, wherein the gate is interposed between the N-type source and the N-type drain; and a body pole is formed, the body pole and the N-type source are located on the same side of the gate, and the N a source is interposed between the body pole and the gate, the body pole is used as an electrical contact of the P-type well region; wherein the P-type well region has one of the first portion and the second portion connected to each other The first portion and the source are located on the same side of the gate, and the first portion and the second portion have a first junction, the first junction being between the gate and the body Between the two views, the first portion is in the width direction of the first junction, and both ends are super The second portion is at least 2 microns.
在其中一種較佳的實施型態中,該操作區具有彼此連接之一第三部分與一第四部分,該第三部分與該源極位於該閘極同側,且該第三部份與該第四部分之間具有一第二接面,該第二接面介於該閘極與該本體極之間,由上視圖視之,該第三部份於該第二接面處之該寬度方向上,兩端皆超過該第四部分至少2微米。In a preferred embodiment, the operating area has a third portion and a fourth portion connected to each other, the third portion and the source are located on the same side of the gate, and the third portion is There is a second junction between the fourth portion, the second junction is between the gate and the body pole, as viewed from a top view, the third portion is at the second junction In the width direction, both ends are at least 2 microns beyond the fourth portion.
在其中一種較佳的實施型態中,該操作區具有一第一作用寬度,且該第一作用寬度不超過5微米。In one preferred embodiment, the operating zone has a first active width and the first active width does not exceed 5 microns.
前述的實施例中,該第四部分具有一第二作用寬度,且該第二作用寬度不超過5微米。In the foregoing embodiments, the fourth portion has a second active width and the second applied width does not exceed 5 microns.
在其中一種較佳的實施型態中,該本體極於該寬度方向上,超過該操作區。In a preferred embodiment, the body extends beyond the operating region in the width direction.
100,200,500‧‧‧N型MOS元件100,200,500‧‧‧N type MOS components
11,21,31,41,51‧‧‧基板11,21,31,41,51‧‧‧substrate
12,22,32,42‧‧‧P型井區12,22,32,42‧‧‧P type well area
13,23,33,43,53‧‧‧隔絕區13,23,33,43,53‧‧ ‧Isolation area
13a,23a,33a,43a,53a‧‧‧操作區13a, 23a, 33a, 43a, 53a‧‧‧ operation area
14,24,34,44,54‧‧‧本體極14,24,34,44,54‧‧‧ body
15,25,35,45,55‧‧‧閘極15,25,35,45,55‧‧‧ gate
16,26,36,46,56‧‧‧源極16,26,36,46,56‧‧‧Source
17,27,37,47,57‧‧‧汲極17,27,37,47,57‧‧‧汲
21a,41a‧‧‧上表面21a, 41a‧‧‧ upper surface
22a,42a‧‧‧第一部分22a, 42a‧‧‧ part one
22b,42b‧‧‧第二部分22b, 42b‧‧‧ part two
22c,42c‧‧‧接面22c, 42c‧‧‧ joint
48‧‧‧N型井區48‧‧‧N type well area
53b‧‧‧第三部分53b‧‧‧Part III
53c‧‧‧第四部分53c‧‧‧Part IV
B‧‧‧基極B‧‧‧ base
C‧‧‧集極C‧‧‧集极
E‧‧‧射極E‧‧‧射极
d ‧‧‧距離 d ‧‧‧distance
w ‧‧‧寬度方向 w ‧‧‧width direction
w1 ‧‧‧作用寬度 W1 ‧‧‧effect width
300,400‧‧‧N型LDMOS元件300,400‧‧‧N type LDMOS components
第1A-1B圖顯示一種習知N型MOS元件100。1A-1B shows a conventional N-type MOS device 100.
第2A-2B圖顯示本發明的第一個實施例。Fig. 2A-2B shows a first embodiment of the present invention.
第3A-3B圖顯示一種習知N型LDMOS元件300。3A-3B shows a conventional N-type LDMOS device 300.
第4A-4B圖顯示本發明的第二個實施例。4A-4B shows a second embodiment of the present invention.
第5圖顯示本發明的第三個實施例。Fig. 5 shows a third embodiment of the present invention.
第6A-6B圖分別舉例顯示利用本發明N型MOS元件的導通饋電壓(ON breakdown voltage)與不導通崩潰防護電壓(OFF breakdown voltage)。6A-6B are diagrams respectively showing an ON breakdown voltage and an OFF breakdown voltage using the N-type MOS device of the present invention.
第7A-7J圖顯示本發明的第四個實施例。Figures 7A-7J show a fourth embodiment of the invention.
第2A-2B圖顯示本發明的第一個實施例。第2A與2B圖分別顯示根據本發明之N型金屬氧化物半導體(metal oxide semiconductor,MOS)元件200的剖視示意圖與上視示意圖。如第2A與2B圖所示,N型MOS元件200包含基板21、P型井區22、隔絕區23、本體極24、閘極25、N型源極26、與N型汲極27。基板21具有上表面21a。其中,基板21例如但不限於為P型矽基鈑,或其他如半導體基板;而上表面21a如第2A圖中虛線所示意。P型井區22形成於上表面21a下。隔絕區23形成於上表面21a上,以定義操作區23a。操作區23a位於P型井區22中,作為N型MOS元件200操作時主要的作用區。而P型井區22、本體極24的導電型為P型,N型源極26與N型汲極27形成於上表面21a下,導電型為N型。閘極25形成於上表面21a上,閘極25介於N型源極26與N型汲極27之間。本體極24與N型源極26形成於閘極25同側,且N型源極26介於本體極24與閘極25之間,本體極24用以作為P型井區22之電性接點。其中,P型井區22具有彼此連接之第一部分22a與第二部分22b,第一部分22a與源極26位於閘極25同側,且第一部份22a與第二部分22b之間具有接面22c,接面22c介於閘極25與本體極24之間,由上視圖第2B圖視之,第一部份22a於接面22c處之寬度方向w 上,兩端皆超過第二部分22b至少2微米,如第2B 圖中距離d 所示意,第一部份22a於接面22c處之寬度方向w 上,兩端皆超過第二部分22b至少一距離d ,也就是說距離d 大於2微米。當然,兩端超過第二部分22b的距離不必須相同,只要超過2微米即可。Fig. 2A-2B shows a first embodiment of the present invention. 2A and 2B are respectively a cross-sectional schematic view and a top view showing an N-type metal oxide semiconductor (MOS) device 200 according to the present invention. As shown in FIGS. 2A and 2B, the N-type MOS device 200 includes a substrate 21, a P-type well region 22, an isolation region 23, a body electrode 24, a gate electrode 25, an N-type source electrode 26, and an N-type drain electrode 27. The substrate 21 has an upper surface 21a. The substrate 21 is, for example but not limited to, a P-type germanium germanium or other semiconductor substrate, and the upper surface 21a is indicated by a broken line in FIG. 2A. The P-type well region 22 is formed below the upper surface 21a. The isolation region 23 is formed on the upper surface 21a to define the operation area 23a. The operation area 23a is located in the P-type well region 22 as a main active area when the N-type MOS element 200 operates. The conductivity type of the P-type well region 22 and the body pole 24 is P-type, and the N-type source electrode 26 and the N-type drain electrode 27 are formed under the upper surface 21a, and the conductivity type is N-type. The gate 25 is formed on the upper surface 21a, and the gate 25 is interposed between the N-type source 26 and the N-type drain 27. The body pole 24 and the N-type source 26 are formed on the same side of the gate 25, and the N-type source 26 is interposed between the body pole 24 and the gate 25, and the body pole 24 is used as the electrical connection of the P-type well region 22. point. The P-type well region 22 has a first portion 22a and a second portion 22b connected to each other. The first portion 22a and the source 26 are located on the same side of the gate 25, and the first portion 22a and the second portion 22b have a junction. 22c, the junction 22c is interposed between the gate 25 and the body pole 24, as viewed from the second view of FIG. 2B, the first portion 22a is in the width direction w of the junction 22c, and both ends exceed the second portion 22b. At least 2 micrometers, as indicated by the distance d in FIG. 2B, the first portion 22a is at least one distance d from the second portion 22b in the width direction w at the junction 22c, that is, the distance d is greater than 2 Micron. Of course, the distance between the two ends beyond the second portion 22b does not have to be the same as long as it exceeds 2 micrometers.
本發明主要的概念在於,設計P型井區在靠近P型本體極極側兩端的寬度,超過靠近N型汲極側(或N型源極另一側)兩端的寬度至少2微米,使得當N型MOS元件操作時,無論是導通操作或不導通操作,其中的寄生BJT的基極阻值Rb可控制在一預設值之下,以避免N型MOS元件在發生累增崩潰前,寄生BJT導通,以致N型MOS元件的崩潰防護電壓降低。The main concept of the present invention is to design a P-type well region at a width close to both ends of the P-type body pole side, exceeding a width of at least 2 microns near the N-type drain side (or the other side of the N-type source), such that when N When the MOS device is operated, whether the conduction operation or the non-conduction operation, the base resistance value Rb of the parasitic BJT can be controlled below a preset value to avoid the parasitic BJT of the N-type MOS device before the cumulative collapse occurs. Turning on, so that the breakdown protection voltage of the N-type MOS device is lowered.
第4A-4B圖顯示本發明的第二個實施例。本實施例旨在說明根據本發明,所謂N型MOS元件,亦包含N型橫向雙擴散金屬氧化物半導體(lateral double diffused metal oxide semiconductor,LDMOS)元件。第4A與4B圖分別顯示根據本發明之N型LDMOS元件400的剖視示意圖與上視示意圖。如第4A與4B圖所示,N型LDMOS元件400包含基板41、P型井區42、隔絕區43、本體極44、閘極45、N型源極46、N型汲極47、與N型井區48。基板41具有上表面41a。其中,基板41例如但不限於為P型矽基鈑,或其他如半導體基板;而上表面41a如第4A圖中虛線所示意。P型井區42形成於上表面41a下。隔絕區43形成於上表面41a上,以定義操作區43a。操作區43a位於N型井區48中,作為N型LDMOS元件400操作時主要的作用區。而P型井區42、本體極44的導電型為P型,N型源極46、N型汲極47、與N型井區48形成於上表面41a下,導電型為N型。閘極45形成於上表面41a上,閘極45介於N型源極46與N型汲極47之間。本體極44與N型源極46形成於閘極45同側,且N型源極46介於本體極44與閘極45之間,本體極44用以作為P型井區42之電性接點。其中,P型井區42具有彼此連接之第一部分42a與第二部分42b,第一部分42a與源極46位於閘極45同側,且第一部份42a與第二部分42b之間具有接面42c,接面42c介於閘極45與本體極44之間,由上視圖第4B圖視之,第一部份42a於接面42c處之寬度方向w 上,兩端皆超過第二部分42b至少2微米,如第4B圖中距離d 所示意,第一部份42a於接面42c處之寬度方向w 上, 兩端皆超過第二部分42b至少一距離d ,也就是說距離d 大於2微米。當然,兩端超過第二部分42b的距離不必須相同,只要超過2微米即可。4A-4B shows a second embodiment of the present invention. This embodiment is intended to illustrate a so-called N-type MOS device according to the present invention, and also includes an N-type lateral double diffused metal oxide semiconductor (LDMOS) device. 4A and 4B are schematic cross-sectional and top views, respectively, showing an N-type LDMOS device 400 in accordance with the present invention. As shown in FIGS. 4A and 4B, the N-type LDMOS device 400 includes a substrate 41, a P-type well region 42, an isolation region 43, a body electrode 44, a gate 45, an N-type source 46, an N-type drain 47, and N. Shape well area 48. The substrate 41 has an upper surface 41a. The substrate 41 is, for example but not limited to, a P-type germanium, or other such as a semiconductor substrate; and the upper surface 41a is indicated by a broken line in FIG. 4A. The P-type well region 42 is formed under the upper surface 41a. The isolation region 43 is formed on the upper surface 41a to define the operation region 43a. The operating zone 43a is located in the N-well zone 48 as the primary active zone for operation of the N-type LDMOS component 400. The conductivity type of the P-type well region 42 and the body pole 44 is P-type, and the N-type source 46, the N-type drain 47, and the N-type well region 48 are formed under the upper surface 41a, and the conductivity type is N-type. The gate 45 is formed on the upper surface 41a, and the gate 45 is interposed between the N-type source 46 and the N-type drain 47. The body pole 44 and the N-type source 46 are formed on the same side of the gate 45, and the N-type source 46 is interposed between the body pole 44 and the gate 45. The body pole 44 is used as the electrical connection of the P-type well region 42. point. Wherein, the P-type well region 42 has a first portion 42a and a second portion 42b connected to each other, the first portion 42a and the source 46 are on the same side of the gate 45, and the junction between the first portion 42a and the second portion 42b 42c, the junction 42c is interposed between the gate 45 and the body pole 44. As viewed from the top view of FIG. 4B, the first portion 42a is in the width direction w of the junction 42c, and both ends exceed the second portion 42b. At least 2 micrometers, as indicated by the distance d in FIG. 4B, the first portion 42a is in the width direction w at the junction 42c, and both ends exceed the second portion 42b by at least one distance d , that is, the distance d is greater than 2 Micron. Of course, the distance between the two ends beyond the second portion 42b does not have to be the same as long as it exceeds 2 micrometers.
第5圖顯示本發明的第三個實施例。第5圖5顯示根據本發明之N型MOS元件500的上視示意圖。如第5圖所示,N型MOS元件500包含基板51、P型井區52、隔絕區53、本體極54、閘極55、N型源極56、與N型汲極57。與第一個實施例不同的是,在本實施例中,除了P型井區52在寬度方向w 上,第一部分兩端皆超過第二部分至少一距離d (未示出,請參照第一個實施例),且距離d 大於2微米之外,如第5圖所示,操作區53a具有彼此連接之第三部分53b與第四部分53c,第三部分53b與源極56位於閘極55同側,且第三部份53b與第四部分53c之間具有接面53d,接面53d介於閘極55與本體極54之間,由上視圖第5圖視之,第三部份53b於接面53d處之寬度方向w上,兩端皆超過第四部分53c至少2微米。本實施例旨在說明,根據本發明,除了可以調整P型井區在閘極靠源極側的寬度外,亦可以調整操作區在閘極靠源極側的寬度,來增加N型MOS元件的崩潰防護電壓。Fig. 5 shows a third embodiment of the present invention. Fig. 5 is a top plan view showing an N-type MOS device 500 according to the present invention. As shown in FIG. 5, the N-type MOS device 500 includes a substrate 51, a P-type well region 52, an isolation region 53, a body electrode 54, a gate 55, an N-type source 56, and an N-type drain 57. Different from the first embodiment, in the embodiment, except that the P-type well region 52 is in the width direction w , both ends of the first portion exceed the second portion by at least one distance d (not shown, please refer to the first An embodiment, and the distance d is greater than 2 microns, as shown in FIG. 5, the operation region 53a has a third portion 53b and a fourth portion 53c connected to each other, and the third portion 53b and the source 56 are located at the gate 55 On the same side, and between the third portion 53b and the fourth portion 53c, there is a junction 53d, and the junction 53d is interposed between the gate 55 and the body pole 54. The fifth portion 53b is viewed from the top view. In the width direction w at the junction 53d, both ends exceed the fourth portion 53c by at least 2 microns. The present embodiment is intended to explain that, according to the present invention, in addition to adjusting the width of the P-type well region on the source side of the gate, the width of the operation region on the source side of the gate can be adjusted to increase the N-type MOS device. The crash protection voltage.
需說明的是,本發明旨在避免N型MOS元件中,寄生BJT導通,而導致崩潰防護電壓下降,較佳的應用範圍,在於N型MOS元件中,如第5圖所示意之作用寬度w1 不超過5微米時。請同時參照第2B圖與第4B圖的作用寬度w1 。此外,一種較佳的實施方式,為本體極54於寬度方向w 上,超過操作區53a(請同時參照第2B圖與第4B圖的本體極24及44,與操作區23a及43a)。It should be noted that the present invention is designed to avoid N-type MOS element, the parasitic BJT is turned on, the voltage drop crash protection, the preferred range of applications, in that the N-type MOS element, as illustrated in FIG. 5, the effect width w1 When not more than 5 microns. Please refer to the action width w1 of FIGS. 2B and 4B at the same time. Further, in a preferred embodiment, the body pole 54 extends beyond the operating region 53a in the width direction w (please refer to both the body poles 24 and 44 of FIGS. 2B and 4B, and the operating regions 23a and 43a).
第6A-6B圖分別舉例顯示利用本發明N型MOS元件的導通崩潰防護電壓(ON breakdown voltage)與不導通崩潰防護電壓(OFF breakdown voltage)。第6A圖顯示根據本發明的N型MOS元件的導通崩潰防護電壓,以限壓方式量測,皆約為40V。第6B圖,顯示根據本發明的N型MOS元件的不導通崩潰防護電壓,以限流方式量測,皆約為35V。表示利用本發明,N型MOS元件可以在作用寬度w1 微縮至不超過5微米時,仍可以維持所需要的崩潰防護電壓,而不因元件尺寸在通道方向上微縮而降低。6A-6B show an example of an ON breakdown voltage and an OFF breakdown voltage using the N-type MOS device of the present invention, respectively. Fig. 6A is a view showing the conduction breakdown voltage of the N-type MOS device according to the present invention, which is measured in a voltage-limiting manner and is about 40V. Fig. 6B is a view showing the non-conduction collapse protection voltage of the N-type MOS device according to the present invention, which is measured by a current limiting method, and is about 35V. It is shown that with the present invention, the N-type MOS device can maintain the required collapse protection voltage even when the effective width w1 is reduced to not more than 5 μm without being reduced by the component size being reduced in the channel direction.
第7A-7J圖顯示本發明的第四個實施例。本實施例舉例說 明本發明之第一個實施例N型MOS元件200的製造方法。為方便說明,第7A-7J圖中,由左而右對照顯示N型MOS元件200的上視示意圖與剖視示意圖。如第7A與7B圖所示,首先提供例如但不限於基板21,其具有上表面21a。接著,例如但不限於以氧化製程形成隔絕區23,其例如為如第7B圖所示之淺溝槽絕緣(shallow trench isolation,STI)結構,亦可以為區域氧化(local oxidation of silicon,LOCOS)結構。於上表面21a上形成隔絕區23,以定義操作區23a如第7A圖所示。Figures 7A-7J show a fourth embodiment of the invention. This example is an example A method of manufacturing the N-type MOS device 200 of the first embodiment of the present invention will be described. For convenience of description, in the drawings of FIGS. 7A-7J, a top view and a cross-sectional view of the N-type MOS device 200 are shown from left to right. As shown in Figures 7A and 7B, first, for example, but not limited to, a substrate 21 having an upper surface 21a is provided. Then, for example, but not limited to, the isolation region 23 is formed by an oxidation process, which is, for example, a shallow trench isolation (STI) structure as shown in FIG. 7B, or may be local oxidation of silicon (LOCOS). structure. An isolation region 23 is formed on the upper surface 21a to define the operation region 23a as shown in Fig. 7A.
接著,如第7C與7D圖所示,例如但不限於以微影製程形成光阻層為遮罩(未示出),以定義P型井區22,並以離子植入製程,將P型雜質,以加速離子的形式,如第7D圖中虛線箭號所示意,植入定義的區域內,而形成P型井區22於上表面21a下。其中,P型井區22具有彼此連接之第一部分22a與第二部分22b,第一部分22a與後續要形成的源極26位於閘極25同側(請參照第2B圖),且第一部份22a與第二部分22b之間具有接面22c,接面22c介於閘極25與本體極24之間,由上視圖第7C圖視之,第一部份22a於接面22c處之寬度方向w 上,兩端皆超過第二部分22b至少2微米,如第7C圖中距離d 所示意。Next, as shown in FIGS. 7C and 7D, for example, but not limited to, forming a photoresist layer as a mask (not shown) by a lithography process to define a P-type well region 22, and using an ion implantation process, the P-type Impurities, in the form of accelerated ions, as indicated by the dashed arrows in Figure 7D, are implanted within defined regions to form a P-type well region 22 below the upper surface 21a. Wherein, the P-type well region 22 has a first portion 22a and a second portion 22b connected to each other, and the first portion 22a and the source 26 to be formed subsequently are located on the same side of the gate 25 (refer to FIG. 2B), and the first portion There is a junction 22c between the 22a and the second portion 22b, and the junction 22c is interposed between the gate 25 and the body pole 24, as viewed from the top view 7C, the width of the first portion 22a at the junction 22c. On w , both ends are at least 2 microns beyond the second portion 22b, as indicated by the distance d in Figure 7C.
接著,如第7E與7F圖所示,形成閘極25於上表面21a上。接著,如第7G與7H圖所示,例如但不限於以微影製程形成光阻層(未示出)與閘極25為遮罩,定義N型源極26與N型汲極27,並以離子植入製程,將N型雜質,以加速離子的形式,如第7H圖中虛線箭號所示意,植入定義的區域內,而形成N型源極26與N型汲極27於上表面21a下,其中,閘極25介於N型源極26與N型汲極27之間。且N型源極26與N型汲極27彼此不互相重疊。Next, as shown in Figs. 7E and 7F, the gate 25 is formed on the upper surface 21a. Next, as shown in FIGS. 7G and 7H, for example, but not limited to, forming a photoresist layer (not shown) and a gate 25 as a mask by a lithography process, defining an N-type source 26 and an N-type drain 27, and In the ion implantation process, the N-type impurity is implanted in the defined region in the form of an accelerated ion, as indicated by the dashed arrow in Fig. 7H, and the N-type source 26 and the N-type drain electrode 27 are formed thereon. Under the surface 21a, the gate 25 is interposed between the N-type source 26 and the N-type drain 27. The N-type source 26 and the N-type drain 27 do not overlap each other.
接著,如第7I與7J圖所示,例如但不限於以微影製程形成光阻層為遮罩(未示出),以定義P型本體極24,並以離子植入製程,將P型雜質,以加速離子的形式,植入定義的區域內,而形成P型本體極24於上表面21a下。其中,本體極24與N型源極26位於閘極25同側,且N型源極26介於本體極24與閘極25之間,本體極24用以作為P型井區22之電性接點。Next, as shown in FIGS. 7I and 7J, for example, but not limited to, forming a photoresist layer as a mask (not shown) by a lithography process to define a P-type body pole 24, and using an ion implantation process, the P-type Impurities, in the form of accelerated ions, are implanted into defined regions to form a P-type body pole 24 below the upper surface 21a. The body pole 24 and the N-type source 26 are located on the same side of the gate 25, and the N-type source 26 is interposed between the body pole 24 and the gate 25, and the body pole 24 is used as the electrical property of the P-type well region 22. contact.
以上已針對較佳實施例來說明本發明,唯以上所述者,僅係為使熟悉本技術者易於了解本發明的內容而已,並非用來限定本發明之權利範圍。在本發明之相同精神下,熟悉本技術者可以思及各種等效變化。例如,在不影響元件主要的特性下,可加入其他製程步驟或結構,如臨界電壓調整區等;又如,微影技術並不限於光罩技術,亦可包含電子束微影技術;再如,除LDMOS元件之外,根據本發明之N型MOS元件亦包括N型雙擴散汲極金屬氧化物半導體(double diffused drain metal oxide semiconductor,DDDMOS)元件、N型雙擴散金屬氧化物半導體(double diffused metal oxide semiconductor,DMOS)元件等。本發明的範圍應涵蓋上述及其他所有等效變化。The present invention has been described with reference to the preferred embodiments thereof, and the present invention is not intended to limit the scope of the present invention. In the same spirit of the invention, various equivalent changes can be conceived by those skilled in the art. For example, other process steps or structures, such as a threshold voltage adjustment region, may be added without affecting the main characteristics of the component; for example, the lithography technology is not limited to the reticle technology, and may also include electron beam lithography; In addition to the LDMOS device, the N-type MOS device according to the present invention also includes an N-type double diffused drain metal oxide semiconductor (DDDMOS) device, and a N-type double diffused metal oxide semiconductor (double diffused). Metal oxide semiconductor, DMOS) components. The above and other equivalent variations are intended to be covered by the scope of the invention.
21‧‧‧基板21‧‧‧Substrate
22‧‧‧P型井區22‧‧‧P type well area
22a‧‧‧第一區22a‧‧‧First District
22b‧‧‧第二區22b‧‧‧Second District
22c‧‧‧接面22c‧‧‧Connected
23‧‧‧隔絕區23‧‧ ‧ isolation zone
23a‧‧‧操作區23a‧‧‧Operating area
24‧‧‧本體極24‧‧‧ body pole
25‧‧‧閘極25‧‧‧ gate
26‧‧‧N型源極26‧‧‧N source
27‧‧‧N型汲極27‧‧‧N type bungee
200‧‧‧N型MOS元件200‧‧‧N type MOS components
d ‧‧‧距離 d ‧‧‧distance
w ‧‧‧寬度方向 w ‧‧‧width direction
w1 ‧‧‧作用寬度 W1 ‧‧‧effect width
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Citations (4)
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TW201032321A (en) * | 2009-02-25 | 2010-09-01 | Univ Ching Yun | Design improvement of butting and inserted pickup in electrostatic discharge (ESD) NMOS's |
US20120187483A1 (en) * | 2011-01-26 | 2012-07-26 | Richtek Technology Corporation, R.O.C. | Double diffused metal oxide semiconductor device and manufacturing method thereof |
JP2013507000A (en) * | 2009-09-30 | 2013-02-28 | スボルタ,インコーポレーテッド | Electronic device and system, and manufacturing method and usage thereof |
TW201316512A (en) * | 2011-10-05 | 2013-04-16 | Macronix Int Co Ltd | MOS device and method of manufacturing the same |
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Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
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TW201032321A (en) * | 2009-02-25 | 2010-09-01 | Univ Ching Yun | Design improvement of butting and inserted pickup in electrostatic discharge (ESD) NMOS's |
JP2013507000A (en) * | 2009-09-30 | 2013-02-28 | スボルタ,インコーポレーテッド | Electronic device and system, and manufacturing method and usage thereof |
US20120187483A1 (en) * | 2011-01-26 | 2012-07-26 | Richtek Technology Corporation, R.O.C. | Double diffused metal oxide semiconductor device and manufacturing method thereof |
TW201316512A (en) * | 2011-10-05 | 2013-04-16 | Macronix Int Co Ltd | MOS device and method of manufacturing the same |
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