Full-field thermal imaging of quasiballistic crosstalk reduction in nanoscale devices

Amirkoushyar Ziabari; Pol Torres; Bjorn Vermeersch; Yi Xuan; Xavier Cartoixà; Alvar Torelló; Je Hyeong Bahk; Yee Rui Koh; Maryam Parsa; Peide D. Ye; F. Xavier Alvarez; Ali Shakouri

doi:10.1038/s41467-017-02652-4

Full-field thermal imaging of quasiballistic crosstalk reduction in nanoscale devices

Amirkoushyar Ziabari, Pol Torres, Bjorn Vermeersch, Yi Xuan, Xavier Cartoixà, Alvar Torelló, Je Hyeong Bahk, Yee Rui Koh, Maryam Parsa, Peide D. Ye, F. Xavier Alvarez, Ali Shakouri

Research output: Contribution to journal › Article › peer-review

66 Scopus citations

Abstract

Understanding nanoscale thermal transport is of substantial importance for designing contemporary semiconductor technologies. Heat removal from small sources is well established to be severely impeded compared to diffusive predictions due to the ballistic nature of the dominant heat carriers. Experimental observations are commonly interpreted through a reduction of effective thermal conductivity, even though most measurements only probe a single aggregate thermal metric. Here, we employ thermoreflectance thermal imaging to directly visualise the 2D temperature field produced by localised heat sources on InGaAs with characteristic widths down to 100 nm. Besides displaying effective thermal performance reductions up to 50% at the active junctions in agreement with prior studies, our steady-state thermal images reveal that, remarkably, 1-3 μm adjacent to submicron devices the crosstalk is actually reduced by up to fourfold. Submicrosecond transient imaging additionally shows responses to be faster than conventionally predicted. A possible explanation based on hydrodynamic heat transport, and some open questions, are discussed.

Original language	English
Article number	255
Journal	Nature Communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-017-02652-4
State	Published - Dec 1 2018
Externally published	Yes

Funding

A.Z. would like to thank Prof. Mark Lundstrom and Dr. Xufeng Wang for their insightful comments and discussions. B.V. acknowledges funding from the ALMA project (European Commission Grant No. 645776). P.T., A.T., F. X.A. and X.C. would like to acknowledge Profs. Juan Camacho, Javier Bafaluy and David Jou for useful discussions regarding hydrodynamic phonon transport. P.T., F.X.A. and X.C. also acknowledge the financial support of the Spanish Ministry of Economy and Competitiveness under grants TEC2015-67462-C2-2-R (MINECO/FEDER) and TEC2015-67462-C2-1-R (MINECO/ FEDER), and the support of the Department d’Universitats, Recerca i Societat de la Informació (DURSI) of the Generalitat de Catalunya under grant 2014-SGR-384.

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title = "Full-field thermal imaging of quasiballistic crosstalk reduction in nanoscale devices",

abstract = "Understanding nanoscale thermal transport is of substantial importance for designing contemporary semiconductor technologies. Heat removal from small sources is well established to be severely impeded compared to diffusive predictions due to the ballistic nature of the dominant heat carriers. Experimental observations are commonly interpreted through a reduction of effective thermal conductivity, even though most measurements only probe a single aggregate thermal metric. Here, we employ thermoreflectance thermal imaging to directly visualise the 2D temperature field produced by localised heat sources on InGaAs with characteristic widths down to 100 nm. Besides displaying effective thermal performance reductions up to 50% at the active junctions in agreement with prior studies, our steady-state thermal images reveal that, remarkably, 1-3 μm adjacent to submicron devices the crosstalk is actually reduced by up to fourfold. Submicrosecond transient imaging additionally shows responses to be faster than conventionally predicted. A possible explanation based on hydrodynamic heat transport, and some open questions, are discussed.",

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AU - Torres, Pol

AU - Vermeersch, Bjorn

AU - Xuan, Yi

AU - Cartoixà, Xavier

AU - Torelló, Alvar

AU - Bahk, Je Hyeong

AU - Koh, Yee Rui

AU - Parsa, Maryam

AU - Ye, Peide D.

AU - Alvarez, F. Xavier

AU - Shakouri, Ali

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Full-field thermal imaging of quasiballistic crosstalk reduction in nanoscale devices

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