公开(公告)号：US20190081079A1

公开(公告)日：2019-03-14

申请号：US16180223

申请日：2018-11-05

Applicant: STMicroelectronics, Inc.

Inventor： Qing Liu ,  Pierre Morin

IPC: H01L27/12 ,  H01L27/092 ,  H01L29/66 ,  H01L21/02 ,  H01L21/324 ,  H01L21/3105 ,  H01L21/308 ,  H01L21/8238 ,  H01L29/78 ,  H01L21/84 ,  H01L29/06 ,  H01L29/10

Abstract: A tensile strained silicon layer is patterned to form a first group of fins in a first substrate area and a second group of fins in a second substrate area. The second group of fins is covered with a tensile strained material, and an anneal is performed to relax the tensile strained silicon semiconductor material in the second group of fins and produce relaxed silicon semiconductor fins in the second area. The first group of fins is covered with a mask, and silicon-germanium material is provided on the relaxed silicon semiconductor fins. Germanium from the silicon germanium material is then driven into the relaxed silicon semiconductor fins to produce compressive strained silicon-germanium semiconductor fins in the second substrate area (from which p-channel finFET devices are formed). The mask is removed to reveal tensile strained silicon semiconductor fins in the first substrate area (from which n-channel finFET devices are formed).

公开(公告)号：US10103174B2

公开(公告)日：2018-10-16

申请号：US14964648

申请日：2015-12-10

Applicant: STMICROELECTRONICS, INC.

Inventor： Pierre Morin ,  Qing Liu ,  Nicolas Loubet

IPC: H01L27/092 ,  H01L27/12 ,  H01L21/84 ,  H01L29/06 ,  H01L29/16 ,  H01L29/161 ,  H01L21/8238

Abstract: A method for making a semiconductor device may include forming, on a first semiconductor layer of a semiconductor-on-insulator (SOI) wafer, a second semiconductor layer comprising a second semiconductor material different than a first semiconductor material of the first semiconductor layer. The method may further include performing a thermal treatment in a non-oxidizing atmosphere to diffuse the second semiconductor material into the first semiconductor layer, and removing the second semiconductor layer.

公开(公告)号：US20180144991A1

公开(公告)日：2018-05-24

申请号：US15874813

申请日：2018-01-18

Applicant: STMICROELECTRONICS, INC.

Inventor： Nicolas Loubet ,  Pierre Morin ,  Yann Mignot

IPC: H01L21/8238 ,  H01L29/417 ,  H01L29/78

CPC classification number: H01L21/823821 ,  H01L21/02381 ,  H01L21/02532 ,  H01L21/76224 ,  H01L21/823807 ,  H01L21/823878 ,  H01L27/0922 ,  H01L27/0924 ,  H01L29/0649 ,  H01L29/165 ,  H01L29/41791 ,  H01L29/4916 ,  H01L29/7842 ,  H01L29/785

Abstract: Integrated circuits are disclosed in which the strain properties of adjacent pFETs and nFETs are independently adjustable. The pFETs include compressive-strained SiGe on a silicon substrate, while the nFETs include tensile-strained silicon on a strain-relaxed SiGe substrate. Adjacent n-type and p-type FinFETs are separated by electrically insulating regions formed by a damascene process. During formation of the insulating regions, the SiGe substrate supporting the n-type devices is permitted to relax elastically, thereby limiting defect formation in the crystal lattice of the SiGe substrate.

公开(公告)号：US09917194B2

公开(公告)日：2018-03-13

申请号：US15365640

申请日：2016-11-30

Applicant: STMicroelectronics, Inc.

Inventor： Nicolas Loubet ,  Pierre Morin

IPC: H01L29/78 ,  H01L27/088 ,  H01L29/49 ,  H01L29/06 ,  H01L29/417 ,  H01L29/10 ,  H01L29/66 ,  H01L29/161

CPC classification number: H01L29/785 ,  H01L27/0886 ,  H01L29/0623 ,  H01L29/0649 ,  H01L29/1054 ,  H01L29/161 ,  H01L29/41791 ,  H01L29/495 ,  H01L29/66545 ,  H01L29/6656 ,  H01L29/66795 ,  H01L29/7849 ,  H01L2029/7858

Abstract: A self-aligned SiGe FinFET device features a relaxed channel region having a high germanium concentration. Instead of first introducing germanium into the channel and then attempting to relax the resulting strained film, a relaxed channel is formed initially to accept the germanium. In this way, a presence of germanium can be established without straining or damaging the lattice. Gate structures are patterned relative to intrinsic silicon fins, to ensure that the gates are properly aligned, prior to introducing germanium into the fin lattice structure. After aligning the gate structures, the silicon fins are segmented to elastically relax the silicon lattice. Then, germanium is introduced into the relaxed silicon lattice, to produce a SiGe channel that is substantially stress-free and also defect-free. Using the method described, concentration of germanium achieved in a structurally stable film can be increased to a level greater than 85%.

公开(公告)号：US09679899B2

公开(公告)日：2017-06-13

申请号：US14833857

申请日：2015-08-24

Applicant: STMicroelectronics, Inc.

Inventor： Nicolas Loubet ,  Pierre Morin ,  Yann Mignot

IPC: H01L27/092 ,  H01L29/165 ,  H01L21/02 ,  H01L21/762 ,  H01L21/8238 ,  H01L29/49 ,  H01L29/78 ,  H01L29/06

CPC classification number: H01L21/823821 ,  H01L21/02381 ,  H01L21/02532 ,  H01L21/76224 ,  H01L21/823807 ,  H01L21/823878 ,  H01L27/0922 ,  H01L27/0924 ,  H01L29/0649 ,  H01L29/165 ,  H01L29/41791 ,  H01L29/4916 ,  H01L29/7842 ,  H01L29/785

Abstract: Integrated circuits are disclosed in which the strain properties of adjacent pFETs and nFETs are independently adjustable. The pFETs include compressive-strained SiGe on a silicon substrate, while the nFETs include tensile-strained silicon on a strain-relaxed SiGe substrate. Adjacent n-type and p-type FinFETs are separated by electrically insulating regions formed by a damascene process. During formation of the insulating regions, the SiGe substrate supporting the n-type devices is permitted to relax elastically, thereby limiting defect formation in the crystal lattice of the SiGe substrate.

公开(公告)号：US09647086B2

公开(公告)日：2017-05-09

申请号：US14826803

申请日：2015-08-14

Applicant: GLOBALFOUNDRIES Inc. ,  International Business Machines Corporations ,  STMicroelectronics, Inc.

Inventor： Steven Bentley ,  Jody Fronheiser ,  Xin Miao ,  Joseph Washington ,  Pierre Morin

IPC: H01L29/66 ,  H01L29/06 ,  H01L21/265 ,  H01L21/324 ,  H01L21/306 ,  H01L21/308 ,  H01L21/02

CPC classification number: H01L29/66537 ,  H01L21/0245 ,  H01L21/02532 ,  H01L21/02538 ,  H01L21/265 ,  H01L21/26513 ,  H01L21/30604 ,  H01L21/3081 ,  H01L21/324 ,  H01L29/0638 ,  H01L29/105 ,  H01L29/1054 ,  H01L29/165

Abstract: A method of performing an early PTS implant and forming a buffer layer under a bulk or fin channel to control doping in the channel and the resulting bulk or fin device are provided. Embodiments include forming a recess in a substrate; forming a PTS layer below a bottom surface of the recess; forming a buffer layer on the bottom surface and on side surfaces of the recess; forming a channel layer on and adjacent to the buffer layer; and annealing the channel, buffer, and PTS layers.

公开(公告)号：US09548361B1

公开(公告)日：2017-01-17

申请号：US14755663

申请日：2015-06-30

Applicant: STMicroelectronics, Inc.

Inventor： Nicolas Loubet ,  Pierre Morin

IPC: H01L29/10 ,  H01L29/66 ,  H01L29/417 ,  H01L29/78 ,  H01L29/06 ,  H01L29/161

CPC classification number: H01L29/785 ,  H01L27/0886 ,  H01L29/0623 ,  H01L29/0649 ,  H01L29/1054 ,  H01L29/161 ,  H01L29/41791 ,  H01L29/495 ,  H01L29/66545 ,  H01L29/6656 ,  H01L29/66795 ,  H01L29/7849 ,  H01L2029/7858

Abstract: A self-aligned SiGe FinFET device features a relaxed channel region having a high germanium concentration. Instead of first introducing germanium into the channel and then attempting to relax the resulting strained film, a relaxed channel is formed initially to accept the germanium. In this way, a presence of germanium can be established without straining or damaging the lattice. Gate structures are patterned relative to intrinsic silicon fins, to ensure that the gates are properly aligned, prior to introducing germanium into the fin lattice structure. After aligning the gate structures, the silicon fins are segmented to elastically relax the silicon lattice. Then, germanium is introduced into the relaxed silicon lattice, to produce a SiGe channel that is substantially stress-free and also defect-free. Using the method described, concentration of germanium achieved in a structurally stable film can be increased to a level greater than 85%.

Abstract translation: 自对准SiGe FinFET器件具有具有高锗浓度的松弛沟道区。 不是首先将锗引入通道，然后尝试松弛所得到的应变膜，最初形成松弛的通道以接受锗。 以这种方式，可以建立锗的存在而不会使晶格变形或损坏。 在将锗引入鳍状晶格结构之前，门结构相对于本征硅散热片图案化，以确保栅极正确对准。 在对齐栅极结构之后，将硅片段分段以弹性地松弛硅晶格。 然后，将锗引入松弛的硅晶格中，以产生基本上无应力且也无缺陷的SiGe沟道。 使用所述方法，在结构稳定的膜中实现的锗的浓度可以增加到大于85％的水平。

公开(公告)号：US09543214B2

公开(公告)日：2017-01-10

申请号：US14526081

申请日：2014-10-28

Applicant: STMicroelectronics SA ,  STMicroelectronics (Crolles 2) SAS ,  STMicroelectronics, Inc.

Inventor： Denis Rideau ,  Elise Baylac ,  Emmanuel Josse ,  Pierre Morin ,  Olivier Nier

IPC: H01L21/8234 ,  H01L21/84 ,  H01L21/762 ,  H01L29/78 ,  H01L21/02 ,  H01L21/265 ,  H01L21/3115 ,  H01L21/308 ,  H01L21/3105 ,  H01L21/324 ,  H01L27/12

CPC classification number: H01L21/823481 ,  H01L21/02356 ,  H01L21/02532 ,  H01L21/265 ,  H01L21/26506 ,  H01L21/3081 ,  H01L21/3105 ,  H01L21/31155 ,  H01L21/324 ,  H01L21/76224 ,  H01L21/76237 ,  H01L21/823431 ,  H01L21/845 ,  H01L27/1203 ,  H01L29/7831 ,  H01L29/7846 ,  H01L29/7847

Abstract: The invention concerns a method of forming a semiconductor layer having uniaxial stress including: forming, in a semiconductor structure having a stressed semiconductor layer, one or more first isolation trenches in a first direction for delimiting a first dimension of at least one transistor to be formed in said semiconductor structure; forming, in the semiconductor structure, one or more second isolation trenches in a second direction for delimiting a second dimension of the at least one transistor, the first and second isolation trenches being at least partially filled with an insulating material; and before or after the formation of the second isolation trenches, decreasing the viscosity of the insulating material in the first isolation trenches by implanting atoms of a first material into the first isolation trenches, wherein atoms of the first material are not implanted into the second isolation trenches.

Abstract translation: 本发明涉及一种形成具有单轴应力的半导体层的方法，包括：在具有应力半导体层的半导体结构中形成在第一方向上的一个或多个第一隔离沟槽，以限定待形成的至少一个晶体管的第一维度 在所述半导体结构中; 在所述半导体结构中，在第二方向上形成用于限定所述至少一个晶体管的第二尺寸的一个或多个第二隔离沟槽，所述第一和第二隔离沟槽至少部分地填充有绝缘材料; 并且在形成第二隔离沟槽之前或之后，通过将第一材料的原子注入到第一隔离沟槽中来降低第一隔离沟槽中的绝缘材料的粘度，其中第一材料的原子未被注入第二隔离层 沟渠

公开(公告)号：US09431538B2

公开(公告)日：2016-08-30

申请号：US14950833

申请日：2015-11-24

Applicant: Commissariat a l'energie atomique et aux energies alternatives ,  STMICROELECTRONICS, Inc.

Inventor： Shay Reboh ,  Pierre Morin

IPC: H01L21/336 ,  H01L29/78 ,  H01L29/16 ,  H01L29/161 ,  H01L29/165 ,  H01L29/66 ,  H01L29/06

CPC classification number: H01L29/7848 ,  H01L29/0649 ,  H01L29/1608 ,  H01L29/161 ,  H01L29/165 ,  H01L29/66545 ,  H01L29/66628 ,  H01L29/66636

Abstract: Method of making at least one transistor strained channel semiconducting structure, comprising steps to form a sacrificial gate block and insulating spacers arranged in contact with the lateral faces of the sacrificial gate block, form sacrificial regions in contact with the lateral faces of said semiconducting zone, said sacrificial regions being configured so as to apply a strain on said semiconducting zone, remove said sacrificial gate block between said insulating spacers, replace said sacrificial gate block by a replacement gate block between said insulating spacers, remove said sacrificial regions, and replace said sacrificial regions by replacement regions in contact with the lateral faces of said semiconducting zone, on a semiconducting zone that will form a transistor channel region.

Abstract translation: 制造至少一个晶体管应变通道半导体结构的方法，包括形成牺牲栅极块的步骤和与牺牲栅极块的侧面接触地布置的绝缘间隔物，形成与所述半导体区域的侧面接触的牺牲区域， 所述牺牲区域被配置为在所述半导体区域上施加应变，去除所述绝缘间隔物之间​​的所述牺牲栅极块，用所述绝缘间隔物之间​​的置换栅极块代替所述牺牲栅极块，去除所述牺牲区域， 区域，其与形成晶体管沟道区域的半导体区域相接触，与所述半导体区域的侧面接触。

公开(公告)号：US20160035820A1

公开(公告)日：2016-02-04

申请号：US14447678

申请日：2014-07-31

Applicant: STMicroelectronics, Inc. ,  Commissariat a l'Energie Atomique et aux Energies Alternatives ,  GLOBALFOUNDRIES Inc.

Inventor： Pierre Morin ,  Maud Vinet ,  Laurent Grenouillet ,  Ajey Poovannummoottil Jacob

IPC: H01L29/06 ,  H01L29/78 ,  H01L29/66

CPC classification number: H01L29/0607 ,  H01L21/02636 ,  H01L21/283 ,  H01L21/3086 ,  H01L21/32 ,  H01L21/762 ,  H01L21/76264 ,  H01L21/823412 ,  H01L21/823418 ,  H01L21/823431 ,  H01L21/823481 ,  H01L21/84 ,  H01L21/845 ,  H01L27/1203 ,  H01L27/1211 ,  H01L29/0653 ,  H01L29/0665 ,  H01L29/1066 ,  H01L29/66477 ,  H01L29/66795 ,  H01L29/78 ,  H01L29/7847 ,  H01L29/7849

Abstract: Methods and structures for forming uniaxially-strained, nanoscale, semiconductor bars from a biaxially-strained semiconductor layer are described. A spatially-doubled mandrel process may be used to form a mask for patterning dense, narrow trenches through the biaxially-strained semiconductor layer. The resulting slicing of the biaxially-strained layer enhances carrier mobility and can increase device performance.