WO2023284481A1 - 体栅横向双扩散金属氧化物半导体场效应管及其制作方法 - Google Patents

体栅横向双扩散金属氧化物半导体场效应管及其制作方法 Download PDF

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WO2023284481A1
WO2023284481A1 PCT/CN2022/099414 CN2022099414W WO2023284481A1 WO 2023284481 A1 WO2023284481 A1 WO 2023284481A1 CN 2022099414 W CN2022099414 W CN 2022099414W WO 2023284481 A1 WO2023284481 A1 WO 2023284481A1
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region
gate
effect transistor
trench
field effect
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French (fr)
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赵景川
何乃龙
张森
姚玉恒
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无锡华润上华科技有限公司
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/66Types of semiconductor device ; Multistep manufacturing processes therefor
    • H01L29/68Types of semiconductor device ; Multistep manufacturing processes therefor controllable by only the electric current supplied, or only the electric potential applied, to an electrode which does not carry the current to be rectified, amplified or switched
    • H01L29/76Unipolar devices, e.g. field effect transistors
    • H01L29/772Field effect transistors
    • H01L29/78Field effect transistors with field effect produced by an insulated gate
    • H01L29/7801DMOS transistors, i.e. MISFETs with a channel accommodating body or base region adjoining a drain drift region
    • H01L29/7816Lateral DMOS transistors, i.e. LDMOS transistors
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/02Semiconductor bodies ; Multistep manufacturing processes therefor
    • H01L29/06Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/02Semiconductor bodies ; Multistep manufacturing processes therefor
    • H01L29/06Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions
    • H01L29/0603Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions characterised by particular constructional design considerations, e.g. for preventing surface leakage, for controlling electric field concentration or for internal isolations regions
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/02Semiconductor bodies ; Multistep manufacturing processes therefor
    • H01L29/06Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions
    • H01L29/0684Semiconductor bodies ; Multistep manufacturing processes therefor characterised by their shape; characterised by the shapes, relative sizes, or dispositions of the semiconductor regions ; characterised by the concentration or distribution of impurities within semiconductor regions characterised by the shape, relative sizes or dispositions of the semiconductor regions or junctions between the regions
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/66Types of semiconductor device ; Multistep manufacturing processes therefor
    • H01L29/66007Multistep manufacturing processes
    • H01L29/66075Multistep manufacturing processes of devices having semiconductor bodies comprising group 14 or group 13/15 materials
    • H01L29/66227Multistep manufacturing processes of devices having semiconductor bodies comprising group 14 or group 13/15 materials the devices being controllable only by the electric current supplied or the electric potential applied, to an electrode which does not carry the current to be rectified, amplified or switched, e.g. three-terminal devices
    • H01L29/66409Unipolar field-effect transistors
    • H01L29/66477Unipolar field-effect transistors with an insulated gate, i.e. MISFET
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/66Types of semiconductor device ; Multistep manufacturing processes therefor
    • H01L29/66007Multistep manufacturing processes
    • H01L29/66075Multistep manufacturing processes of devices having semiconductor bodies comprising group 14 or group 13/15 materials
    • H01L29/66227Multistep manufacturing processes of devices having semiconductor bodies comprising group 14 or group 13/15 materials the devices being controllable only by the electric current supplied or the electric potential applied, to an electrode which does not carry the current to be rectified, amplified or switched, e.g. three-terminal devices
    • H01L29/66409Unipolar field-effect transistors
    • H01L29/66477Unipolar field-effect transistors with an insulated gate, i.e. MISFET
    • H01L29/66674DMOS transistors, i.e. MISFETs with a channel accommodating body or base region adjoining a drain drift region
    • H01L29/66681Lateral DMOS transistors, i.e. LDMOS transistors
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L29/00Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
    • H01L29/66Types of semiconductor device ; Multistep manufacturing processes therefor
    • H01L29/68Types of semiconductor device ; Multistep manufacturing processes therefor controllable by only the electric current supplied, or only the electric potential applied, to an electrode which does not carry the current to be rectified, amplified or switched
    • H01L29/76Unipolar devices, e.g. field effect transistors
    • H01L29/772Field effect transistors
    • H01L29/78Field effect transistors with field effect produced by an insulated gate

Definitions

  • the invention belongs to the field of semiconductor device design and manufacture, in particular to a method for manufacturing a body gate lateral double-diffused metal oxide semiconductor field effect transistor.
  • LDMOS laterally-diffused metal-oxide semiconductor field-effect transistor
  • As arsenic
  • B boron
  • LDMOS Since boron diffuses faster than arsenic, it will diffuse further along the lateral direction under the gate boundary, forming a channel with a concentration gradient, and its channel length is determined by the difference between the two lateral diffusion distances.
  • the drift region in LDMOS is the key to the design of this type of device.
  • the impurity concentration in the drift region is relatively low. Therefore, when the LDMOS is connected to a high voltage, the drift region can withstand a higher voltage due to its high resistance.
  • LDMOS the core device in monolithic integrated power ICs
  • On-resistance optimization is one of the key factors to improve LDMOS performance.
  • RESURF reduced surface field technology
  • surface super junction the most common ones are: reduced surface field technology (RESURF) and surface super junction.
  • the object of the present invention is to provide a method for manufacturing a body-gate lateral double-diffused metal-oxide-semiconductor field-effect transistor, which is used to solve the problem of high on-resistance of LDMOS devices in the prior art .
  • the present invention provides a body gate lateral double-diffused metal oxide semiconductor field effect transistor, the field effect transistor includes: a substrate; a drift region of the first conductivity type formed on the substrate On the bottom; a body region of the second conductivity type is formed in the drift region; a source region of the first conductivity type is formed on the surface layer of the body region; a body lead-out region of the second conductivity type is formed in the body region The surface layer; the drain region of the first conductivity type is formed on the surface layer of the drift region and arranged at intervals from the body region; the auxiliary depletion region of the second conductivity type is formed between the body region and the drain region The surface layer of the drift region between; the gate structure, straddling the source region and the drift region; the body gate structure, including a plurality of body trench gates distributed in the auxiliary depletion region and the body The lead-out structure of the trench gate.
  • the body trench gate includes a trench located in the auxiliary depletion region, an in-trench dielectric layer located on a sidewall of the trench, and a conductive medium filled in the in-trench dielectric layer, the The depth of the trench is smaller than the depth of the auxiliary depletion region.
  • the body trench gates between any adjacent two body trench gate columns are arranged in a dislocation along the second direction.
  • the body trench gate applies a first voltage with the same polarity as the gate structure, so as to reduce the on-resistance of the field effect transistor; when the When the field effect transistor is turned off, a second voltage opposite to the first voltage is applied to the body trench gate, so as to increase the reverse withstand voltage of the field effect transistor.
  • the depth of the auxiliary depletion region ranges from 2 microns to 4 microns
  • the width of the body trench gates ranges from 1 micron to 2 microns
  • the distance between two adjacent body trench gates ranges from 2 microns to 2 microns. 3 microns.
  • an insulating layer is further formed on the body gate structure, a through hole exposing the body trench gate is formed in the insulating layer, and the body trench is formed on the through hole and the insulating layer.
  • Grid lead-out structure is further formed on the body gate structure, a through hole exposing the body trench gate is formed in the insulating layer, and the body trench is formed on the through hole and the insulating layer.
  • the present invention also provides a method for manufacturing a body-gate lateral double-diffused metal oxide semiconductor field effect transistor, comprising the steps of: providing a substrate, and forming a drift region of the first conductivity type on the substrate; Auxiliary depletion regions of the second conductivity type are formed on the surface layer of the auxiliary depletion region; a plurality of body trench gates are formed in the auxiliary depletion regions; body regions of the second conductivity type are formed in the drift region; A source region of the first conductivity type and a body lead-out region of the second conductivity type form a drain region of the first conductivity type on the surface layer of the drift region, wherein the auxiliary depletion region is located between the drain region and the body region forming a gate structure between the source region and the drift region; forming an extraction structure on the body trench gate.
  • forming a plurality of body trench gates in the auxiliary depletion region includes: etching a plurality of trenches in the auxiliary depletion region through a photolithography process and an etching process, and the depth of the trenches is less than the depth of the auxiliary depletion region; forming an in-trench dielectric layer on the sidewall of the trench through a thermal oxidation process; filling a conductive medium in the in-trench dielectric layer through a deposition process.
  • the drift region is formed by an ion implantation process and a high temperature push junction process.
  • forming an extraction structure on the body trench gate includes the steps of: forming an insulating layer on the surface of the drift region; forming a via hole exposing the body trench gate in the insulating layer, based on the via The hole forms an extraction structure of the body trench gate.
  • the method for fabricating a body-gate lateral double-diffused metal-oxide-semiconductor field-effect transistor of the present invention has the following beneficial effects:
  • the body trench gates of the present invention are arranged at intervals along a first direction to form a plurality of body trench gate columns, and are arranged at intervals to form a plurality of body trench gate rows along a second direction, the first direction being the direction from the source region to the drain region , each bulk trench grid row is led out by a gate line, any gate line is drawn out to an independent control terminal, or multiple gate lines are drawn out to a common control terminal, by adjusting the voltage applied to the independent control terminal or the common control terminal, The resistance or depletion of the drift region can be effectively adjusted, and the application range or application field of the field effect transistor can be expanded.
  • FIG. 2 is a schematic cross-sectional structure diagram of a body-gate lateral double-diffused metal-oxide-semiconductor field effect transistor according to an embodiment of the present invention.
  • the source region 106 of the first conductivity type and the body extraction region 105 of the second conductivity type are formed on the surface layer of the body region 104, and the doping concentration of the body extraction region 105 is 1E15cm ⁇ 3 to 5E15cm -3 , the doping concentration of the source region 106 is 2E15cm -3 to 4E15cm -3 .
  • the source region 106 of the first conductivity type and the body lead-out region 105 of the second conductivity type are adjacently arranged to make the device more compact and reduce the device area.
  • the drain region 108 of the first conductivity type is formed on the surface layer of the drift region 102 and spaced apart from the body region 104 .
  • the field effect transistor further includes a buffer region 103 of the first conductivity type located between the drain region 108 and the drift region 102, and the doping concentration of the buffer region 103 is preferably lower than that of the drain region 108.
  • the doping concentration is greater than the doping concentration of the drift region 102
  • the junction depth of the buffer region 103 is greater than the junction depth of the drain region 108 and smaller than the junction depth of the drift region 102 .
  • the doping concentration of the buffer zone 103 ranges from 1E12cm ⁇ 3 to 4E12cm ⁇ 3 , and the buffer zone 103 can effectively increase the on-state breakdown voltage of the field effect transistor in forward conduction.
  • the body gate structure includes a plurality of body trench gates 100 distributed in the auxiliary depletion region 111 and an extraction structure of the body trench gates 100 .
  • an insulating layer 113 is further formed on the body gate structure, and a through hole exposing the body trench gate 100 is formed in the insulating layer 113, and the through hole and the insulating layer 113 are formed There is an extraction structure of the body trench gate 100 .
  • the function of the body trench gate 100 in the device is different from that of the gate structure 107 in the device, and the potential connected to the body trench gate 100 is the same as or different from the potential connected to the gate structure 107 . That is to say, the gate structure 107 directly controls the turn-on and turn-off of the device channel, which is a gate in the general sense of the device, and the body trench gate 100 controls the trench in the auxiliary depletion region 111 The surrounding region is inverted, which belongs to the control structure for inverting the auxiliary depletion region 111 .
  • each 100 rows of trench gates is led out by a gate line 112, and any one of the gate lines 112 is led out to an independent control terminal IO1, IO2, IO3...IOn, as shown in Figure 3, or A plurality of the gate lines 112 are led out to a common control terminal.
  • a plurality of the body trench gates 100 may also be arranged in a matrix array or in other ways, which is not limited to the examples listed here.
  • the first direction is the direction from the source region 106 to the drain region 108 (that is, the first direction is the length direction of the conductive channel of the device), and the second direction is the direction of the conductive channel of the device. width direction.
  • the potentials applied to the body trench gate 100 and the gate structure 107 are both high potentials relative to the source region 106, and the body trench
  • the potentials applied to the gate 100 and the gate structure 107 may be different or the same. That is, the voltage applied to each independent control terminal IO1, IO2, IO3...IOn is different from or the same as the voltage applied by the gate structure 107, and the voltage applied to each independent control terminal IO1, IO2, IO3...IOn can also be same or different.
  • step 1) is performed, a substrate 101 is provided, and a drift region 102 of the first conductivity type is formed on the substrate 101 .
  • the substrate 101 may be a semiconductor substrate, such as a Si substrate, a Ge substrate, a SiGe substrate, SOI (silicon on insulator) or GOI (germanium on insulator) and the like.
  • the semiconductor substrate can also be a substrate including other elemental semiconductors or compound semiconductors, such as GaAs, InP or SiC, etc., or a stacked structure, such as Si/SiGe, etc., or other Epitaxial structure, such as SGOI (silicon germanium on insulator), etc.
  • the substrate is a Si substrate with high resistivity, and the resistivity of the substrate is preferably 60ohm. cm ⁇ 140ohm. cm.
  • the body gate LDMOS of this embodiment can achieve substrate depletion through a Si substrate with a higher resistivity, thereby increasing the breakdown voltage of the body gate LDMOS.
  • the substrate in this embodiment is of the second conductivity type.
  • the drift region 102 of the first conductivity type may be formed on the substrate by vapor phase epitaxy or ion implantation followed by high-temperature push junction, and the material of the drift region 102 may be the same as or different from that of the substrate 101.
  • the drift region 102 is made of the same silicon material as that of the substrate 101 .
  • the depth range of the drift region 102 is 10 micrometers to 20 micrometers, and the doping concentration range of the drift region 102 is 3.5E12cm ⁇ 3 to 6.5E12cm ⁇ 3 , so as to ensure that the substrate 101 of the body gate LDMOS is depleted At the same time, the current conduction path during conduction can be guaranteed.
  • the width of the body trench gates 100 is 1 micron to 2 microns, and the distance between two adjacent body trench gates 100 is 2 microns to 3 microns.
  • Step 3-3) filling the dielectric layer 109 with a conductive medium 110 through a deposition process, and the conductive medium 110 may be, for example, a polysilicon layer.
  • each 100 rows of trench gates is led out by a gate line 112, and any one of the gate lines 112 is led out to an independent control terminal IO1, IO2, IO3...IOn, as shown in Figure 3, or A plurality of the gate lines 112 are led out to a common control terminal.
  • the resistance or depletion of the drift region 102 can be effectively adjusted, and the application range or application field of the field effect transistor can be expanded.
  • the first direction is the direction from the source region 106 to the drain region 108 (that is, the first direction is the length direction of the conductive channel of the device), and the second direction is the direction of the conductive channel of the device. width direction.
  • step 5 is performed to form a source region 106 of the first conductivity type and a body lead-out region 105 of the second conductivity type on the surface layer of the body region 104, and form a first conductivity type region 105 on the surface layer of the drift region 102.
  • the drain region 108 wherein the auxiliary depletion region 111 is located between the drain region 108 and the body region 104 .
  • the doping concentration of the body lead-out region 105 is 1E15cm -3 -5E15cm -3
  • the doping concentration of the source region 106 is 2E15cm -3 -4E15cm -3 .
  • the source region 106 of the first conductivity type and the body lead-out region 105 of the second conductivity type are adjacently arranged to make the device more compact and reduce the device area.
  • step 7) is performed to form a gate structure 107 between the source region 106 and the drift region 102, and the gate structure 107 is used to control the turn-on and turn-off of the channel below it. .
  • step 8 is performed to form a through hole exposing the body trench gate 100 in the insulating layer 113 , and an extraction structure of the body trench gate 100 is formed based on the through hole.
  • the body trench gate 100 when the field effect transistor is conducting forward, the body trench gate 100 is applied with the same pole as the gate structure 107 .
  • the positive first voltage attracts carriers near the bulk trench gate 100, realizes the inversion of the conductivity type of the auxiliary depletion region 111, increases the concentration of the majority carriers 114 in the drift region 102, and reduces the field effect The on-resistance of the tube.
  • the body trench gate 100 applies a second voltage opposite in polarity to the first voltage to adjust the depletion capability to increase the reverse withstand voltage of the field effect transistor.
  • the body trench gates 100 of the present invention are arranged at intervals along a first direction into a plurality of columns of body trench gates 100, and are arranged at intervals of a plurality of rows of body trench gates 100 along a second direction.
  • the first direction is that the source region 106 faces In the direction of the drain region 108, the body trench gates 100 between any two adjacent columns of body trench gates 100 are arranged in a dislocation in the second direction, and each row of body trench gates 100 is led out by a gate line 112.
  • One gate line 112 leads to an independent control terminal, or multiple gate lines 112 lead to a common control terminal, by adjusting the voltage applied to the independent control terminal or the common control terminal, the resistance or depletion of the drift region 102 can be effectively adjusted , Expand the application range or application field of the field effect tube.

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Abstract

本发明提供一种体栅横向双扩散金属氧化物半导体场效应管及其制作方法,包括:衬底;第一导电类型的漂移区;第二导电类型的体区;第一导电类型的源区,形成于体区内;第二导电类型的体引出区,形成于体区内;第一导电类型的漏区,形成于漂移区内,并与体区间隔排布;第二导电类型的辅助耗尽区,形成于体区与漏区之间的漂移区的表层;栅极结构,横跨于源区与漂移区之上;体栅结构,包括分布于辅助耗尽区内的多个体沟槽栅以及体沟槽栅的引出结构。当场效应管正向导通时,体沟槽栅施加与栅极结构相同极性的第一电压,以降低场效应管的导通电阻;当场效应管关断时,体沟槽栅施加与第一电压极性相反的第二电压,以提高场效应管的反向耐压。

Description

体栅横向双扩散金属氧化物半导体场效应管及其制作方法
相关申请的交叉引用
本申请要求于2021年7月16日提交中国专利局、申请号为202110806790.2、发明名称为“体栅横向双扩散金属氧化物半导体场效应管及其制作方法”的中国专利申请的优先权,其全部内容通过引用结合在本申请中。
技术领域
本发明属于半导体器件设计及制造领域,特别是涉及一种体栅横向双扩散金属氧化物半导体场效应管的制作方法。
背景技术
横向双扩散金属氧化物半导体场效应管(LDMOS,laterally-diffused metal-oxide semiconductor)是在高压功率集成电路中常采用高压LDMOS以满足耐高压、可实现功率控制等方面的要求,常用于射频功率电路。LDMOS是一种双扩散结构的功率器件,需要在相同的源、漏区域注入两次,一次注入浓度较大的砷(As),另一次注入浓度较小的硼(B);注入之后再进行一个高温推进过程。由于硼扩散比砷快,所以在栅极边界下会沿着横向扩散更远,形成一个有浓度梯度的沟道,它的沟道长度由这两次横向扩散的距离之差决定。为了增加击穿电压,在有源区和漏区之间有一个漂移区。LDMOS中的漂移区是该类器件设计的关键,漂移区的杂质浓度比较低,因此,当LDMOS接高压时,漂移区由于是高阻,能够承受更高的电压。
随着高压功率器件的发展,单片集成功率IC中核心器件LDMOS性能尤为重要。导通电阻的优化是提高LDMOS性能的关键因素之一。在现阶段的LDMOS器件中,通过对漂移区结构优化来降低导通电阻的方法越来越多,最常见的为:降低表面场技术(RESURF)以及表面超结等。
发明内容
鉴于以上所述现有技术的缺点,本发明的目的在于提供一种体栅横向双扩散金属氧化物半导体场效应管的制作方法,用于解决现有技术中LDMOS器件导通电阻较高的问题。
为实现上述目的及其他相关目的,本发明提供一种体栅横向双扩散金属氧化物半导体 场效应管,所述场效应管包括:衬底;第一导电类型的漂移区,形成于所述衬底上;第二导电类型的体区,形成于所述漂移区内;第一导电类型的源区,形成于所述体区表层;第二导电类型的体引出区,形成于所述体区表层;第一导电类型的漏区,形成于所述漂移区表层,并与所述体区间隔排布;第二导电类型的辅助耗尽区,形成于所述体区与所述漏区之间的漂移区的表层;栅极结构,横跨于所述源区与所述漂移区之上;体栅结构,包括分布于所述辅助耗尽区内的多个体沟槽栅以及所述体沟槽栅的引出结构。
可选地,所述体沟槽栅包括位于所述辅助耗尽区的沟槽、位于所述沟槽侧壁的槽内介质层以及填充于所述槽内介质层内的导电介质,所述沟槽的深度小于所述辅助耗尽区的深度。
可选地,多个所述体沟槽栅沿第一方向间隔排布成多个体沟槽栅列,沿第二方向间隔排布成多个体沟槽栅行,所述第一方向为源区朝向漏区的方向,所述第二方向与所述第一方向交叉,其中,每一体沟槽栅行由一栅线引出,任一所述栅线引出至一独立控制端,或多个所述栅线引出至一共用控制端。
可选地,任意相邻的两体沟槽栅列之间的体沟槽栅在第二方向上呈错位排布。
可选地,当所述场效应管正向导通时,所述体沟槽栅施加与所述栅极结构相同极性的第一电压,以降低所述场效应管的导通电阻;当所述场效应管关断时,所述体沟槽栅施加与所述第一电压极性相反的第二电压,以提高所述场效应管的反向耐压。
可选地,所述辅助耗尽区的深度范围为2微米~4微米,所述体沟槽栅的宽度为1微米~2微米,相邻两体沟槽栅之间的间距为2微米~3微米。
可选地,所述体栅结构上还形成有绝缘层,所述绝缘层中形成显露所述体沟槽栅的通孔,所述通孔及所述绝缘层上形成有所述体沟槽栅的引出结构。
本发明还提供一种体栅横向双扩散金属氧化物半导体场效应管的制作方法,包括步骤:提供一衬底,于所述衬底上形成第一导电类型的漂移区;于所述漂移区的表层形成第二导电类型的辅助耗尽区;于所述辅助耗尽区中形成多个体沟槽栅;于所述漂移区中形成第二导电类型的体区;于所述体区表层形成第一导电类型的源区和第二导电类型的体引出区,于所述漂移区表层形成第一导电类型的漏区,其中,所述辅助耗尽区位于所述漏区与所述体区之间;于所述源区与所述漂移区之间形成栅极结构;于所述体沟槽栅上形成引出结构。
可选地,于所述辅助耗尽区中形成多个体沟槽栅包括:通过光刻工艺及刻蚀工艺于所述辅助耗尽区中刻蚀出多个沟槽,所述沟槽的深度小于所述辅助耗尽区的深度;通过热氧化工艺于所述沟槽的侧壁形成槽内介质层;通过淀积工艺于所述槽内介质层内填充导电介质。
可选地,于所述辅助耗尽区中形成的多个体沟槽栅沿第一方向间隔排布成多个体沟槽栅列,沿第二方向间隔排布成多个体沟槽栅行,所述第一方向为源区朝向漏区的方向,所述第二方向与所述第一方向交叉,其中,任意相邻的两体沟槽栅列之间的体沟槽栅在第二方向上呈错位排布;基于所述通孔形成所述体沟槽栅的引出结构包括多个栅线,每一体沟槽栅行由一栅线引出,任一所述栅线引出至一独立控制端,或多个所述栅线引出至一共用控制端。
可选地,所述漂移区通过离子注入工艺及高温推结工艺形成。
可选地,所述辅助耗尽区的深度范围为2微米~4微米,所述体沟槽栅的宽度为1微米~2微米,相邻两体沟槽栅之间的间距为2微米~3微米。
可选地,于所述体沟槽栅上形成引出结构包括步骤:于所述漂移区表面形成绝缘层;于所述绝缘层中形成显露所述体沟槽栅的通孔,基于所述通孔形成所述体沟槽栅的引出结构。
如上所述,本发明的体栅横向双扩散金属氧化物半导体场效应管的制作方法,具有以下有益效果:
本发明在漂移区内形成一定深度且呈阵列排布的体沟槽栅,体沟槽栅的深度不大于辅助耗尽区的深度,在场效应管正向导通时,体沟槽栅可以施加与所述栅极结构相同极性的第一电压例如与栅极结构一同加电压,在体沟槽栅附近吸引载流子,实现将辅助耗尽区的导电类型的反型,提高漂移区内多数载流子浓度,从而大大降低器件的导通电阻,当所述场效应管关断时,体沟槽栅施加与栅极结构极性相反的电压,以提高所述场效应管的反向耐压。
本发明的体沟槽栅沿第一方向间隔排布成多个体沟槽栅列,沿第二方向间隔排布成多个体沟槽栅行,所述第一方向为源区朝向漏区的方向,每一体沟槽栅行由一栅线引出,任一栅线引出至一独立控制端,或多个栅线引出至一共用控制端,通过调整对独立控制端或共用控制端施加的电压,可以有效调整漂移区的电阻或耗尽情况,拓展场效应管的应用范围或应用领域。
附图说明
图1显示为本发明实施例的体栅横向双扩散金属氧化物半导体场效应管的三维立体结构示意图。
图2显示为本发明实施例的体栅横向双扩散金属氧化物半导体场效应管的截面结构示意图。
图3显示为本发明实施例的体栅横向双扩散金属氧化物半导体场效应管的在导通时可降低导通电阻的原理示意图。
图4~图11显示为本发明实施例的体栅横向双扩散金属氧化物半导体场效应管的制作方法各步骤所呈现的结构示意图。
元件标号说明
100                    体沟槽栅
101                    衬底
102                    漂移区
103                    缓冲区
104                    体区
105                    体引出区
106                    源区
107                    栅极结构
108                    漏区
109                    槽内介质层
110                    导电介质
111                    辅助耗尽区
112                    栅线
113                    绝缘层
114                    多数载流子
具体实施方式
以下通过特定的具体实例说明本发明的实施方式,本领域技术人员可由本说明书所揭露的内容轻易地了解本发明的其他优点与功效。本发明还可以通过另外不同的具体实施方式加以实施或应用,本说明书中的各项细节也可以基于不同观点与应用,在没有背离本发明的精神下进行各种修饰或改变。
如在详述本发明实施例时,为便于说明,表示器件结构的剖面图会不依一般比例作局部放大,而且所述示意图只是示例,其在此不应限制本发明保护的范围。此外,在实际制作中应包含长度、宽度及深度的三维空间尺寸。
为了方便描述,此处可能使用诸如“之下”、“下方”、“低于”、“下面”、“上方”、“上” 等的空间关系词语来描述附图中所示的一个元件或特征与其他元件或特征的关系。应当理解的是,这些空间关系词语意图包含使用中或操作中的器件的、除了附图中描绘的方向之外的其他方向。此外,当一层被称为在两层“之间”时,它可以是所述两层之间仅有的层,或者也可以存在一个或多个介于其间的层。
在本申请的上下文中,所描述的第一特征在第二特征“之上”的结构可以包括第一和第二特征形成为直接接触的实施例,也可以包括另外的特征形成在第一和第二特征之间的实施例,这样第一和第二特征可能不是直接接触。
需要说明的是,本实施例中所提供的图示仅以示意方式说明本发明的基本构想,遂图示中仅显示与本发明中有关的组件而非按照实际实施时的组件数目、形状及尺寸绘制,其实际实施时各组件的型态、数量及比例可为一种随意的改变,且其组件布局型态也可能更为复杂。
如图1~图3所示,其中,图1显示为本实施例的体栅横向双扩散金属氧化物半导体场效应管的三维立体结构示意图,其中,为了能充分展示本实施例的体栅横向双扩散金属氧化物半导体场效应管的全部特征形貌,图1中示意地切除了体沟槽栅上方的部分绝缘层和引出结构,其并不代表本实施例的体栅横向双扩散金属氧化物半导体场效应管的最终形貌,图2显示为本实施例的体栅横向双扩散金属氧化物半导体场效应管的截面结构示意图。本实施例提供一种体栅横向双扩散金属氧化物半导体场效应管(体栅LDMOS),所述场效应管包括衬底101、第一导电类型的漂移区102、第二导电类型的体区104、第一导电类型的源区106、第二导电类型的体引出区105、第一导电类型的漏区108、第二导电类型的辅助耗尽区111、栅极结构107及体栅结构。
作为示例,所述衬底可以为半导体衬底,例如可以为Si衬底、Ge衬底、SiGe衬底、SOI(绝缘体上硅)或GOI(绝缘体上锗)等。在其它实施例中,所述半导体衬底还可以为包括其它元素半导体或化合物半导体的衬底,例如GaAs、InP或SiC等,还可以为叠层结构,例如Si/SiGe等,还可以为其它外延结构,例如SGOI(绝缘体上锗硅)等。在本实施例中,所述衬底为高电阻率的Si衬底,所述衬底的电阻率优选为60ohm﹒cm~140ohm﹒cm。本实施例的体栅LDMOS可以通过较高电阻率的Si衬底来实现衬底耗尽,从而提高体栅LDMOS的击穿电压。
如图2所示,所述第一导电类型的漂移区102形成于所述衬底101上。所述漂移区102的材料可以与所述衬底101相同或不同,且所述漂移区102的导电类型与所述衬底101的导电类型相反。在本实施例中,所述漂移区102选用为与所述衬底101相同的硅材料,所述衬底101为第二导电类型。所述漂移区102的深度范围为10微米~20微米,所述漂移区 102的掺杂浓度范围为3.5E12cm -3~6.5E12cm -3,从而既能保证体栅LDMOS的衬底101耗尽的同时,又能保证导通时的电流导通路径。
如图2所示,所述第二导电类型的体区104形成于所述漂移区102内。在本实施例中,所述体区104自所述漂移区102的上表面穿透至所述漂移区102的下表面,并与所述衬底101接触,所述体区104的掺杂浓度为2E12cm -3~4E12cm -3。在本实施例中,所述第一导电类型为N型导电,所述第二导电类型为P型导电。当然,在其他的实施中,所述第一导电类型也可以为P型导电,所述第二导电类型也可以为N型导电。
如图2所示,所述第一导电类型的源区106及所述第二导电类型的体引出区105形成于所述体区104表层,所述体引出区105的掺杂浓度为1E15cm -3~5E15cm -3,所述源区106的掺杂浓度为2E15cm -3~4E15cm -3。在本实施例中,所述第一导电类型的源区106及所述第二导电类型的体引出区105相邻设置,以使器件更加紧凑,缩小器件面积。
如图2所示,所述第一导电类型的漏区108形成于所述漂移区102表层,并与所述体区104间隔排布。在本实施例中,所述场效应管还包括位于漏区108与漂移区102之间的第一导电类型的缓冲区103,所述缓冲区103的掺杂浓度优选为小于所述漏区108的掺杂浓度,且大于所述漂移区102的掺杂浓度,所述缓冲区103的结深大于所述漏区108的结深且小于所述漂移区102的结深。优选地,所述缓冲区103的掺杂浓度范围为1E12cm -3~4E12cm -3,所述缓冲区103可以有效提高场效应管在正向导通时的开态击穿电压。
如图2所示,所述第二导电类型的辅助耗尽区111形成于所述体区104与所述漏区108之间的漂移区102的表层。在本实施例中,所述辅助耗尽区111的深度范围为2微米~4微米,也即所述辅助耗尽区111的结深范围为2微米~4微米。所述辅助耗尽区111可以辅助所述漂移区102耗尽,提升器件反向耐压性能。
如图2所示,所述栅极结构107横跨于所述源区106与所述漂移区102之上,也可以理解为栅极结构形成于所述体区104的上表面,所述栅极结构107的一侧与所述源区106邻接或覆盖部分所述源区106,所述栅极结构107的另一侧覆盖部分所述漂移区102。所述栅极结构107用于控制其下方的沟道的导通和关闭。
如图2所示,所述体栅结构包括分布于所述辅助耗尽区111内的多个体沟槽栅100以及所述体沟槽栅100的引出结构。在本实施例中,所述体栅结构上还形成有绝缘层113,所述绝缘层113中形成显露所述体沟槽栅100的通孔,所述通孔及所述绝缘层113上形成有所述体沟槽栅100的引出结构。
作为示例,所述体沟槽栅100包括位于所述辅助耗尽区111的沟槽、位于所述沟槽侧壁的槽内介质层109以及填充于所述槽内介质层109内的导电介质110,所述沟槽的深度 小于所述辅助耗尽区111的深度。所述体沟槽栅100的宽度为1微米~2微米,相邻两体沟槽栅100之间的间距为2微米~3微米。所述体沟槽栅100用于控制所述辅助耗尽区111内的所述沟槽周围的区域反型,能大大降低器件的导通电阻。所述体沟槽栅100在器件中的作用与所述栅极结构107在器件做的作用不同,所述体沟槽栅100外接的电位与所述栅极结构107外接的电位相同或不同。也即所述栅极结构107直接控制器件沟道的导通和关闭,是器件通常意义上的栅极,而所述体沟槽栅100控制所述辅助耗尽区111内的所述沟槽周围的区域反型,属于使所述辅助耗尽区111反型的控制结构。
在本实施例中,多个所述体沟槽栅100沿第一方向间隔排布成多个体沟槽栅100列,沿第二方向间隔排布成多个体沟槽栅100行,所述第一方向为源区106朝向漏区108的方向,所述第二方向与所述第一方向交叉,其中,任意相邻的两体沟槽栅100列之间的体沟槽栅100在第二方向上呈错位排布,每一体沟槽栅100行由一栅线112引出,任一所述栅线112引出至一独立控制端IO1、IO2、IO3……IOn,如图3所示,或多个所述栅线112引出至一共用控制端。当然,在其他的实施例中,多个所述体沟槽栅100也可以成矩阵阵列排列或其他方式排列,并不限于此处所列举的示例。在本实施例中,通过调整对独立控制端或共用控制端施加的电压,可以有效调整漂移区102的电阻或耗尽情况,拓展场效应管的应用范围或应用领域。在其他实施例中,所述第一方向为源区106朝向漏区108的方向(也即所述第一方向为器件的导电沟道长度方向),所述第二方向为器件的导电沟道宽度方向。
如图3所示,本发明的体栅横向双扩散金属氧化物半导体场效应管,当所述场效应管正向导通时,所述体沟槽栅100施加与所述栅极结构107相同极性的第一电压,在体沟槽栅100附近吸引载流子,实现将辅助耗尽区111的导电类型的反型,提高漂移区102内多数载流子114浓度,以降低所述场效应管的导通电阻。在其他实施例中,当所述场效应管正向导通时,所述体沟槽栅100与所述栅极结构107施加的电位相对于源区106,均为高电位,所述体沟槽栅100与所述栅极结构107施加的电位大小可以不同,也可以相同。也即对各独立控制端IO1、IO2、IO3……IOn施加的电压与所述栅极结构107施加的电压不同或相同,且各独立控制端IO1、IO2、IO3……IOn施加的电压也可以相同或不同。
当所述场效应管关断时,所述体沟槽栅100施加与所述第一电压极性相反的第二电压,以提高所述场效应管的反向耐压。在其他实施例中,当所述场效应管关断时,所述体沟槽栅100施加的电压与所述栅极结构107施加的电压不同,也即对各独立控制端IO1、IO2、IO3……IOn施加的电压与所述栅极结构107施加的电压不同,且对各独立控制端IO1、IO2、IO3……IOn施加的电压依次降低。
如图4~图11所示,本实施例还提供一种体栅横向双扩散金属氧化物半导体场效应管的制作方法,包括步骤:
如图4所示,进行步骤1),提供一衬底101,于所述衬底101上形成第一导电类型的漂移区102。
作为示例,所述衬底101可以为半导体衬底,例如可以为Si衬底、Ge衬底、SiGe衬底、SOI(绝缘体上硅)或GOI(绝缘体上锗)等。在其它实施例中,所述半导体衬底还可以为包括其它元素半导体或化合物半导体的衬底,例如GaAs、InP或SiC等,还可以为叠层结构,例如Si/SiGe等,还可以为其它外延结构,例如SGOI(绝缘体上锗硅)等。在本实施例中,所述衬底为高电阻率的Si衬底,所述衬底的电阻率优选为60ohm﹒cm~140ohm﹒cm。本实施例的体栅LDMOS可以通过较高电阻率的Si衬底来实现衬底耗尽,从而提高体栅LDMOS的击穿电压。本实施例中的衬底为第二导电类型。
例如,可以通过气相外延工艺或通过离子注入后高温推结于所述衬底上形成第一导电类型的漂移区102,所述漂移区102的材料可以与所述衬底101相同或不同,在本实施例中,所述漂移区102选用为与所述衬底101相同的硅材料。所述漂移区102的深度范围为10微米~20微米,所述漂移区102的掺杂浓度范围为3.5E12cm -3~6.5E12cm -3,从而既能保证体栅LDMOS的衬底101耗尽的同时,又能保证导通时的电流导通路径。
如图5所示,进行步骤2),于所述漂移区102的表层形成第二导电类型的辅助耗尽区111。
在本实施例中,可以通过离子注入后高温推结形成所述辅助耗尽区111,所述辅助耗尽区111的深度范围为2微米~4微米。所述辅助耗尽区111可以辅助所述漂移区102耗尽,提升器件反向耐压性能。
如图6所示,进行步骤3),于所述辅助耗尽区111中形成多个体沟槽栅100。
具体地,于所述辅助耗尽区111中形成多个体沟槽栅100包括:
步骤3-1)通过光刻工艺及刻蚀工艺于所述辅助耗尽区111中刻蚀出多个沟槽,所述沟槽的深度小于所述辅助耗尽区111的深度。
在本实施例中,于所述辅助耗尽区111中形成的多个体沟槽栅100沿第一方向间隔排布成多个体沟槽栅100列,沿第二方向间隔排布成多个体沟槽栅100行,所述第一方向为源区106朝向漏区108的方向,所述第二方向与所述第一方向交叉,其中,任意相邻的两体沟槽栅100列之间的体沟槽栅100在第二方向上呈错位排布。当然,在其他的实施例中,多个所述体沟槽栅100也可以成矩阵排列或其他方式排列,并不限于此处所列举的示例。
在本实施例中,所述体沟槽栅100的宽度为1微米~2微米,相邻两体沟槽栅100之间 的间距为2微米~3微米。
步骤3-2),通过热氧化工艺于所述沟槽的侧壁形成槽内介质层109。
步骤3-3),通过淀积工艺于所述槽内介质层109内填充导电介质110,所述导电介质110例如可以为多晶硅层。
在本实施例中,多个所述体沟槽栅100沿第一方向间隔排布成多个体沟槽栅100列,沿第二方向间隔排布成多个体沟槽栅100行,所述第一方向为源区106朝向漏区108的方向,所述第二方向与所述第一方向交叉,其中,任意相邻的两体沟槽栅100列之间的体沟槽栅100在第二方向上呈错位排布,每一体沟槽栅100行由一栅线112引出,任一所述栅线112引出至一独立控制端IO1、IO2、IO3……IOn,如图3所示,或多个所述栅线112引出至一共用控制端。在本实施例中,通过调整对独立控制端或共用控制端施加的电压,可以有效调整漂移区102的电阻或耗尽情况,拓展场效应管的应用范围或应用领域。在其他实施例中,所述第一方向为源区106朝向漏区108的方向(也即所述第一方向为器件的导电沟道长度方向),所述第二方向为器件的导电沟道宽度方向。
如图7所示,进行步骤4),于所述漂移区102中形成第二导电类型的体区104。
在本实施例中,所述体区104自所述漂移区102的上表面穿透至所述漂移区102的下表面,并与所述衬底101接触,所述体区104的掺杂浓度为2E12cm -3~4E12cm -3。在本实施例中,所述第一导电类型为N型导电,所述第二导电类型为P型导电。当然,在其他的实施中,所述第一导电类型也可以为P型导电,所述第二导电类型也可以为N型导电。
如图8所示,进行步骤5),于所述体区104表层形成第一导电类型的源区106和第二导电类型的体引出区105,于所述漂移区102表层形成第一导电类型的漏区108,其中,所述辅助耗尽区111位于所述漏区108与所述体区104之间。
所述体引出区105的掺杂浓度为1E15cm -3~5E15cm -3,所述源区106的掺杂浓度为2E15cm -3~4E15cm -3。在本实施例中,所述第一导电类型的源区106及所述第二导电类型的体引出区105相邻设置,以使器件更加紧凑,缩小器件面积。
在本实施例中,还在漏区108与漂移区102之间形成第一导电类型的缓冲区103,所述缓冲区103的掺杂浓度优选为小于所述漏区108的掺杂浓度,且大于所述漂移区102的掺杂浓度,所述缓冲区103的结深大于所述漏区108的结深且小于所述漂移区102的结深。优选地,所述缓冲区103的掺杂浓度范围为1E12cm -3~4E12cm -3,所述缓冲区103可以有效提高场效应管在正向导通时的开态击穿电压。
如图9所示,进行步骤6),于所述漂移区102表面形成绝缘层113。例如,可以采用如热氧化工艺或等离子增强化学气相沉积工艺等于所述漂移区102表面形成绝缘层113, 所述绝缘层113可以为二氧化硅。
如图10所示,进行步骤7),于所述源区106与所述漂移区102之间形成栅极结构107,所述栅极结构107用于控制其下方的沟道的导通和关闭。
如图11所示,进行步骤8),于所述绝缘层113中形成显露所述体沟槽栅100的通孔,基于所述通孔形成所述体沟槽栅100的引出结构。
在本实施例中,基于所述通孔形成所述体沟槽栅100的引出结构包括多个栅线112,每一体沟槽栅100行由一栅线112引出,任一所述栅线112引出至一独立控制端IO1、IO2、IO3……IOn,或多个所述栅线112引出至一共用控制端。在本实施例中,通过调整对独立控制端或共用控制端施加的电压,可以有效调整漂移区102的电阻或耗尽情况,拓展场效应管的应用范围或应用领域。
如图3所示,本发明的体栅横向双扩散金属氧化物半导体场效应管,当所述场效应管正向导通时,所述体沟槽栅100施加与所述栅极结构107相同极性的第一电压,在体沟槽栅100附近吸引载流子,实现将辅助耗尽区111的导电类型的反型,提高漂移区102内多数载流子114浓度,以降低所述场效应管的导通电阻。当所述场效应管关断时,所述体沟槽栅100施加与所述第一电压极性相反的第二电压,调节耗尽能力,以提高所述场效应管的反向耐压。
如上所述,本发明的体栅横向双扩散金属氧化物半导体场效应管的制作方法,具有以下有益效果:
本发明在漂移区102内形成一定深度且呈阵列排布的体沟槽栅100,体沟槽栅100的深度不大于辅助耗尽区111的深度,在场效应管正向导通时,体沟槽栅100可以施加与所述栅极结构107相同极性的第一电压例如与栅极结构107一同加电压,在体沟槽栅100附近吸引载流子,实现将辅助耗尽区111的导电类型的反型,提高漂移区102内多数载流子114浓度,从而大大降低器件的导通电阻;当所述场效应管关断时,体沟槽栅100施加与栅极结构107极性相反的电压,以提高所述场效应管的反向耐压。
本发明的体沟槽栅100沿第一方向间隔排布成多个体沟槽栅100列,沿第二方向间隔排布成多个体沟槽栅100行,所述第一方向为源区106朝向漏区108的方向,任意相邻的两体沟槽栅100列之间的体沟槽栅100在第二方向上呈错位排布,每一体沟槽栅100行由一栅线112引出,任一栅线112引出至一独立控制端,或多个栅线112引出至一共用控制端,通过调整对独立控制端或共用控制端施加的电压,可以有效调整漂移区102的电阻或耗尽情况,拓展场效应管的应用范围或应用领域。
所以,本发明有效克服了现有技术中的种种缺点而具高度产业利用价值。
上述实施例仅例示性说明本发明的原理及其功效,而非用于限制本发明。任何熟悉此技术的人士皆可在不违背本发明的精神及范畴下,对上述实施例进行修饰或改变。因此,举凡所属技术领域中具有通常知识者在未脱离本发明所揭示的精神与技术思想下所完成的一切等效修饰或改变,仍应由本发明的权利要求所涵盖。

Claims (15)

  1. 一种体栅横向双扩散金属氧化物半导体场效应管,其特征在于,所述场效应管包括:
    衬底;
    第一导电类型的漂移区,形成于所述衬底上;
    第二导电类型的体区,形成于所述漂移区内;
    第一导电类型的源区,形成于所述体区表层;
    第二导电类型的体引出区,形成于所述体区表层;
    第一导电类型的漏区,形成于所述漂移区表层,并与所述体区间隔排布;
    第二导电类型的辅助耗尽区,形成于所述体区与所述漏区之间的所述漂移区的表层;
    栅极结构,横跨于所述源区与所述漂移区之上;
    体栅结构,包括分布于所述辅助耗尽区内的多个体沟槽栅以及所述体沟槽栅的引出结构。
  2. 根据权利要求1所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:所述体沟槽栅包括位于所述辅助耗尽区的沟槽、位于所述沟槽侧壁的槽内介质层以及填充于所述槽内介质层内的导电介质,所述沟槽的深度小于所述辅助耗尽区的深度。
  3. 根据权利要求1所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:多个所述体沟槽栅沿第一方向间隔排布成多个体沟槽栅列,沿第二方向间隔排布成多个体沟槽栅行,所述第一方向为所述源区朝向所述漏区的方向,所述第二方向与所述第一方向交叉,其中,每一所述体沟槽栅行由一栅线引出,任一所述栅线引出至一独立控制端,或多个所述栅线引出至一共用控制端。
  4. 根据权利要求3所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:任意相邻的两所述体沟槽栅列之间的所述体沟槽栅在所述第二方向上呈错位排布。
  5. 根据权利要求1所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:当所述场效应管正向导通时,所述体沟槽栅施加与所述栅极结构相同极性的第一电压,以降低所述场效应管的导通电阻;当所述场效应管关断时,所述体沟槽栅施加与所述第一电压极性相反的第二电压,以提高所述场效应管的反向耐压。
  6. 根据权利要求1所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:所 述辅助耗尽区的深度范围为2微米~4微米,所述体沟槽栅的宽度为1微米~2微米,相邻两所述体沟槽栅之间的间距为2微米~3微米。
  7. 根据权利要求1所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:所述体栅结构上还形成有绝缘层,所述绝缘层中形成显露所述体沟槽栅的通孔,所述通孔及所述绝缘层上形成有所述体沟槽栅的引出结构。
  8. 根据权利要求1所述的体栅横向双扩散金属氧化物半导体场效应管,其特征在于:在所述漏区与所述漂移区之间形成第一导电类型的缓冲区;所述缓冲区的掺杂浓度小于所述漏区的掺杂浓度,且大于所述漂移区的掺杂浓度;所述缓冲区的结深大于所述漏区的结深且小于所述漂移区的结深。
  9. 一种体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于,包括步骤:
    提供一衬底,于所述衬底上形成第一导电类型的漂移区;
    于所述漂移区的表层形成第二导电类型的辅助耗尽区;
    于所述辅助耗尽区中形成多个体沟槽栅;
    于所述漂移区中形成第二导电类型的体区;
    于所述体区表层形成第一导电类型的源区和第二导电类型的体引出区,于所述漂移区表层形成第一导电类型的漏区,其中,所述辅助耗尽区位于所述漏区与所述体区之间;
    于所述源区与所述漂移区之间形成栅极结构;
    于所述体沟槽栅上形成引出结构。
  10. 根据权利要求9所述的体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于:于所述辅助耗尽区中形成多个体沟槽栅包括:
    通过光刻工艺及刻蚀工艺于所述辅助耗尽区中刻蚀出多个沟槽,所述沟槽的深度小于所述辅助耗尽区的深度;
    通过热氧化工艺于所述沟槽的侧壁形成槽内介质层;
    通过淀积工艺于所述槽内介质层内填充导电介质。
  11. 根据权利要求9所述的体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于:
    于所述辅助耗尽区中形成的多个所述体沟槽栅沿第一方向间隔排布成多个体沟槽栅 列,沿第二方向间隔排布成多个体沟槽栅行,所述第一方向为所述源区朝向所述漏区的方向,所述第二方向与所述第一方向交叉,其中,任意相邻的两所述体沟槽栅列之间的所述体沟槽栅在所述第二方向上呈错位排布。
  12. 根据权利要求9所述的体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于:所述漂移区通过离子注入工艺及高温推结工艺形成。
  13. 根据权利要求9所述的体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于:所述辅助耗尽区的深度范围为2微米~4微米,所述体沟槽栅的宽度为1微米~2微米,相邻两所述体沟槽栅之间的间距为2微米~3微米。
  14. 根据权利要求11所述的体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于,于所述体沟槽栅上形成引出结构包括步骤:
    于所述漂移区表面形成绝缘层;
    于所述绝缘层中形成显露所述体沟槽栅的通孔,基于所述通孔形成所述体沟槽栅的引出结构。
  15. 根据权利要求14所述的体栅横向双扩散金属氧化物半导体场效应管的制作方法,其特征在于,基于所述通孔形成所述体沟槽栅的引出结构包括多个栅线,每一所述体沟槽栅行由一所述栅线引出,任一所述栅线引出至一独立控制端,或多个所述栅线引出至一共用控制端。
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN117712122A (zh) * 2024-02-08 2024-03-15 深圳天狼芯半导体有限公司 碳化硅igbt的结构、制造方法及电子设备

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20100063576A (ko) * 2008-12-03 2010-06-11 한국전자통신연구원 고전압 ldmos 트랜지스터 및 그 제조 방법
CN110459599A (zh) * 2019-08-31 2019-11-15 电子科技大学 具有深埋层的纵向浮空场板器件及制造方法
CN110518059A (zh) * 2019-08-31 2019-11-29 电子科技大学 具有电荷平衡耐压层的纵向浮空场板器件及其制造方法
CN111640787A (zh) * 2020-06-12 2020-09-08 电子科技大学 一种具有多沟槽的ldmos器件

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20100063576A (ko) * 2008-12-03 2010-06-11 한국전자통신연구원 고전압 ldmos 트랜지스터 및 그 제조 방법
CN110459599A (zh) * 2019-08-31 2019-11-15 电子科技大学 具有深埋层的纵向浮空场板器件及制造方法
CN110518059A (zh) * 2019-08-31 2019-11-29 电子科技大学 具有电荷平衡耐压层的纵向浮空场板器件及其制造方法
CN111640787A (zh) * 2020-06-12 2020-09-08 电子科技大学 一种具有多沟槽的ldmos器件

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN117712122A (zh) * 2024-02-08 2024-03-15 深圳天狼芯半导体有限公司 碳化硅igbt的结构、制造方法及电子设备
CN117712122B (zh) * 2024-02-08 2024-04-26 深圳天狼芯半导体有限公司 碳化硅igbt的结构、制造方法及电子设备

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