The dynamics of nickelidation for self-aligned contacts to InGaAs channels

The rapid development of ultrascaled III−V compound-semiconductor devices requires the detailed investigation of metal-semiconductor contacts at the nanoscale where crystal orientation, size, and structural phase play dominant roles in device performance. Here, we report comprehensive studies on the...

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Main Authors:	Chen, Renjie, Dai, Xing, Jungjohann, Katherine L., Mook, William Moyer, Nogan, John, Soci, Cesare, Dayeh, Shadi
Other Authors:	School of Physical and Mathematical Sciences
Format:	Article
Language:	English
Published:	2019
Subjects:	AFM Topography InGaAs DRNTU::Science::Physics
Online Access:	https://hdl.handle.net/10356/106868 http://hdl.handle.net/10220/48992
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Institution:	Nanyang Technological University
Language:	English

id	sg-ntu-dr.10356-106868
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spelling	sg-ntu-dr.10356-1068682023-02-28T19:47:29Z The dynamics of nickelidation for self-aligned contacts to InGaAs channels Chen, Renjie Dai, Xing Jungjohann, Katherine L. Mook, William Moyer Nogan, John Soci, Cesare Dayeh, Shadi School of Physical and Mathematical Sciences AFM Topography InGaAs DRNTU::Science::Physics The rapid development of ultrascaled III−V compound-semiconductor devices requires the detailed investigation of metal-semiconductor contacts at the nanoscale where crystal orientation, size, and structural phase play dominant roles in device performance. Here, we report comprehensive studies on the solid-state reaction between metal (Ni) and ternary III−V semiconductor (In0.53Ga0.47As) nanochannels to reveal their reaction kinetics, dynamics, formed crystal structure, and interfacial properties. We observed size-dependent reaction kinetics that are dominated by Ni surface-diffusion at small channel dimensions. We also employed in-situ heating in a transmission electron microscope (TEM) to record and analyze the atomic scale dynamics of contact reactions both in the cross-section and along the nanowire channel directions of InGaAs nanowires. Atomic models and nucleation models were introduced to depict the ledge formation and nucleation events. Deformation theory was applied to calculate the strain-induced shift in band-edge energies at the nickelide/InGaAs interface. These observations pave the way for engineered nanoscale contact to III-V transistors. Published version 2019-06-27T08:09:25Z 2019-12-06T22:20:00Z 2019-06-27T08:09:25Z 2019-12-06T22:20:00Z 2017 Journal Article Chen, R., Dai, X., Jungjohann, K. L., Mook, W. M., Nogan, J., Soci, C., & Dayeh, S. (2017). The Dynamics of Nickelidation for Self-Aligned Contacts to InGaAs Channels. ECS Transactions, 80(1), 53-69. doi:10.1149/08001.0053ecst 1938-5862 https://hdl.handle.net/10356/106868 http://hdl.handle.net/10220/48992 10.1149/08001.0053ecst en ECS Transactions © 2017 The Electrochemical Society. All rights reserved. This paper was published in ECS Transactions and is made available with permission of The Electrochemical Society. 17 p. application/pdf
institution	Nanyang Technological University
building	NTU Library
continent	Asia
country	Singapore Singapore
content_provider	NTU Library
collection	DR-NTU
language	English
topic	AFM Topography InGaAs DRNTU::Science::Physics
spellingShingle	AFM Topography InGaAs DRNTU::Science::Physics Chen, Renjie Dai, Xing Jungjohann, Katherine L. Mook, William Moyer Nogan, John Soci, Cesare Dayeh, Shadi The dynamics of nickelidation for self-aligned contacts to InGaAs channels
description	The rapid development of ultrascaled III−V compound-semiconductor devices requires the detailed investigation of metal-semiconductor contacts at the nanoscale where crystal orientation, size, and structural phase play dominant roles in device performance. Here, we report comprehensive studies on the solid-state reaction between metal (Ni) and ternary III−V semiconductor (In0.53Ga0.47As) nanochannels to reveal their reaction kinetics, dynamics, formed crystal structure, and interfacial properties. We observed size-dependent reaction kinetics that are dominated by Ni surface-diffusion at small channel dimensions. We also employed in-situ heating in a transmission electron microscope (TEM) to record and analyze the atomic scale dynamics of contact reactions both in the cross-section and along the nanowire channel directions of InGaAs nanowires. Atomic models and nucleation models were introduced to depict the ledge formation and nucleation events. Deformation theory was applied to calculate the strain-induced shift in band-edge energies at the nickelide/InGaAs interface. These observations pave the way for engineered nanoscale contact to III-V transistors.
author2	School of Physical and Mathematical Sciences
author_facet	School of Physical and Mathematical Sciences Chen, Renjie Dai, Xing Jungjohann, Katherine L. Mook, William Moyer Nogan, John Soci, Cesare Dayeh, Shadi
format	Article
author	Chen, Renjie Dai, Xing Jungjohann, Katherine L. Mook, William Moyer Nogan, John Soci, Cesare Dayeh, Shadi
author_sort	Chen, Renjie
title	The dynamics of nickelidation for self-aligned contacts to InGaAs channels
title_short	The dynamics of nickelidation for self-aligned contacts to InGaAs channels
title_full	The dynamics of nickelidation for self-aligned contacts to InGaAs channels
title_fullStr	The dynamics of nickelidation for self-aligned contacts to InGaAs channels
title_full_unstemmed	The dynamics of nickelidation for self-aligned contacts to InGaAs channels
title_sort	dynamics of nickelidation for self-aligned contacts to ingaas channels
publishDate	2019
url	https://hdl.handle.net/10356/106868 http://hdl.handle.net/10220/48992
_version_	1759856593232461824

The dynamics of nickelidation for self-aligned contacts to InGaAs channels

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