公开(公告)号：US20180158933A1

公开(公告)日：2018-06-07

申请号：US15576468

申请日：2015-06-27

Applicant: Intel Corporation

Inventor： Van H. LE ,  Gilbert DEWEY ,  Benjamin CHU-KUNG ,  Ashish AGRAWAL ,  Matthew V. METZ ,  Willy RACHMADY ,  Marc C. FRENCH ,  Jack T. KAVALIEROS ,  Rafael RIOS ,  Seiyon KIM ,  Seung Hoon SUNG ,  Sanaz K. GARDNER ,  James M. POWERS ,  Sherry R. TAFT

IPC: H01L29/66 ,  H01L29/786

CPC classification number: H01L29/66977 ,  H01L29/1054 ,  H01L29/66742 ,  H01L29/66795 ,  H01L29/78 ,  H01L29/785 ,  H01L29/78609 ,  H01L29/78684 ,  H01L29/78696

Abstract: A method including forming a non-planar conducting channel of a device between junction regions on a substrate, the substrate including a blocking material beneath the channel, the blocking material including a property to inhibit carrier leakage; and forming a gate stack on the channel, the gate stack including a dielectric material and a gate electrode. A method including forming a buffer material on a semiconductor substrate, the buffer material including a semiconductor material including a different lattice structure than the substrate; forming a blocking material on the buffer material, the blocking material including a property to inhibit carrier leakage; and forming a transistor device on the substrate. An apparatus including a non-planar multi-gate device on a substrate including a transistor device including a channel disposed on a substrate including a blocking material beneath the channel, the blocking material including a property to inhibit carrier leakage.

公开(公告)号：US20180151684A1

公开(公告)日：2018-05-31

申请号：US15576253

申请日：2015-06-27

Applicant: Intel Corporation

Inventor： Benjamin CHU-KUNG ,  Van H. LE ,  Rafael RIOS ,  Gilbert DEWEY ,  Scott B. CLENDENNING ,  Jack T. KAVALIEROS

IPC: H01L29/45 ,  H01L21/768 ,  H01L21/285 ,  H01L29/417 ,  H01L29/66 ,  H01L29/78

CPC classification number: H01L29/45 ,  H01L21/28556 ,  H01L21/28568 ,  H01L21/76802 ,  H01L21/76883 ,  H01L23/49827 ,  H01L23/49838 ,  H01L29/0847 ,  H01L29/41783 ,  H01L29/66568 ,  H01L29/78

Abstract: An apparatus including an integrated circuit device including at least one low density of state metal/semiconductor material interface, wherein the at least one low density of state metal is quantized. An apparatus including an integrated circuit device including at least one interface of a low density of state metal and a semiconductor material, wherein a contact area of the metal at the interface is graded. A method including confining a contact area of a semiconductor material; and forming a metal contact in the contact area.

公开(公告)号：US20180145077A1

公开(公告)日：2018-05-24

申请号：US15574820

申请日：2015-06-26

Applicant: Intel Corporation

Inventor： Gilbert DEWEY ,  Matthew V. METZ ,  Anand S. MURTHY ,  Tahir GHANI ,  Willy RACHMADY ,  Chandra S. MOHAPATRA ,  Jack T. KAVALIEROS ,  Glenn A. GLASS

IPC: H01L27/092 ,  H01L29/205 ,  H01L29/10 ,  H01L29/423 ,  H01L29/08 ,  H01L29/78 ,  H01L29/66 ,  H01L21/8238

CPC classification number: H01L27/0924 ,  H01L21/823807 ,  H01L21/823814 ,  H01L21/823821 ,  H01L21/82385 ,  H01L21/8258 ,  H01L29/0847 ,  H01L29/1037 ,  H01L29/205 ,  H01L29/42376 ,  H01L29/66522 ,  H01L29/66545 ,  H01L29/66795 ,  H01L29/7851

Abstract: Monolithic FETs including a majority carrier channel in a first high carrier mobility semiconductor material disposed over a substrate. While a mask, such as a gate stack or sacrificial gate stack, is covering a lateral channel region, a spacer of a high carrier mobility semiconductor material is overgrown, for example wrapping around a dielectric lateral spacer, to increase effective spacing between the transistor source and drain without a concomitant increase in transistor footprint. Source/drain regions couple electrically to the lateral channel region through the high-mobility semiconductor spacer, which may be substantially undoped (i.e. intrinsic). With effective channel length for a given lateral gate dimension increased, the transistor footprint for a given off-state leakage may be reduced or off-state source/drain leakage for a given transistor footprint may be reduced, for example.

公开(公告)号：US20170317187A1

公开(公告)日：2017-11-02

申请号：US15528793

申请日：2014-12-23

Applicant: INTEL CORPORATION

Inventor： Sanaz K. GARDNER ,  Willy RACHMADY ,  Matthew V. METZ ,  Gilbert DEWEY ,  Jack T. KAVALIEROS ,  Chandra S. MOHAPATRA ,  Anand S. MURTHY ,  Nadia RAHHAL-ORABI ,  Nancy M. ZELICK ,  Marc C. FRENCH ,  Tahir GHANI

IPC: H01L29/66 ,  H01L29/786 ,  H01L29/423 ,  H01L29/06 ,  H01L27/088 ,  H01L21/8234 ,  H01L21/02

CPC classification number: H01L29/66742 ,  B82Y10/00 ,  H01L21/02392 ,  H01L21/02546 ,  H01L21/02603 ,  H01L21/823412 ,  H01L27/088 ,  H01L29/0673 ,  H01L29/20 ,  H01L29/42392 ,  H01L29/66469 ,  H01L29/66522 ,  H01L29/66795 ,  H01L29/775 ,  H01L29/785 ,  H01L29/78681 ,  H01L29/78696

Abstract: An embodiment includes a device comprising: first and second fins adjacent one another and each including channel and subfin layers, the channel layers having bottom surfaces directly contacting upper surfaces of the subfin layers; wherein (a) the bottom surfaces are generally coplanar with one another and are generally flat; (b) the upper surfaces are generally coplanar with one another and are generally flat; and (c) the channel layers include an upper material and the subfin layers include a lower III-V material different from the upper III-V material. Other embodiments are described herein.

公开(公告)号：US20150325481A1

公开(公告)日：2015-11-12

申请号：US14798380

申请日：2015-07-13

Applicant: Intel Corporation

Inventor： Marko RADOSAVLJEVIC ,  Ravi PILLARISETTY ,  Gilbert DEWEY ,  Niloy MUKHERJEE ,  Jack KAVALIEROS ,  Willy RACHMADY ,  Van LE ,  Benjamin CHU-KUNG ,  Matthew METZ ,  Robert CHAU

IPC: H01L21/8258 ,  H01L21/8238 ,  H01L29/423 ,  H01L21/02 ,  H01L29/16 ,  H01L29/20 ,  H01L21/306 ,  H01L27/092 ,  H01L29/06

CPC classification number: H01L21/845 ,  B82Y10/00 ,  H01L21/0228 ,  H01L21/02532 ,  H01L21/02546 ,  H01L21/30604 ,  H01L21/823807 ,  H01L21/823821 ,  H01L21/8258 ,  H01L27/092 ,  H01L27/0922 ,  H01L27/0924 ,  H01L27/1211 ,  H01L29/0673 ,  H01L29/16 ,  H01L29/20 ,  H01L29/205 ,  H01L29/42392 ,  H01L29/66439 ,  H01L29/66469 ,  H01L29/775 ,  H01L29/785 ,  H01L29/7853 ,  H01L29/78696

Abstract: Architectures and techniques for co-integration of heterogeneous materials, such as group III-V semiconductor materials and group IV semiconductors (e.g., Ge) on a same substrate (e.g. silicon). In embodiments, multi-layer heterogeneous semiconductor material stacks having alternating nanowire and sacrificial layers are employed to release nanowires and permit formation of a coaxial gate structure that completely surrounds a channel region of the nanowire transistor. In embodiments, individual PMOS and NMOS channel semiconductor materials are co-integrated with a starting substrate having a blanket layers of alternating Ge/III-V layers. In embodiments, vertical integration of a plurality of stacked nanowires within an individual PMOS and individual NMOS device enable significant drive current for a given layout area.

Abstract translation: 在同一衬底（例如硅）上的非均质材料如III-V族半导体材料和IV族半导体（例如Ge）共同整合的体系结构和技术。 在实施例中，采用具有交替的纳米线和牺牲层的多层非均相半导体材料堆叠以释放纳米线并允许形成完全包围纳米线晶体管的沟道区域的同轴栅极结构。 在实施例中，各个PMOS和NMOS沟道半导体材料与具有交替的Ge / III-V层的覆盖层的起始衬底共同整合。 在实施例中，单个PMOS和单独NMOS器件内的多个堆叠的纳米线的垂直积分能够给出给定布局区域的显着的驱动电流。