Nanoscale power and heat management in electronics

Andrey Y. Serov; Zuanyi Li; Kyle L. Grosse; Albert D. Liao; David Estrada; Myung Ho Bae; Feng Xiong; William P. King; Eric Pop

doi:10.1109/ICICDT.2012.6232852

Nanoscale power and heat management in electronics

Andrey Y. Serov, Zuanyi Li, Kyle L. Grosse, Albert D. Liao, David Estrada, Myung Ho Bae, Feng Xiong, William P. King, Eric Pop

Micron School of Materials Science and Engineering

University of Illinois at Urbana-Champaign

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Power consumption and heat dissipation are significant challenges in electronics ranging from mobile devices to large data centers. A fundamental examination of energy dissipation in such contexts can lead to orders of magnitude improvements in energy efficiency. We present recent highlights from our work examining power and heat dissipation in nanoscale device geometries, at contacts or interfaces, and when novel materials are involved. For instance, thermal conductivity is significantly reduced in nanostructures due to the role of boundary scattering. However relatively unusual effects such as quasi-ballistic and thermoelectric transport could be used to partially mitigate the heat generated during device operation. In addition, careful low-power device design from the outset can alleviate heat dissipation problems before they begin. For example, data storage based on phase-change (rather than charge) with carbon nanotube electrodes can lead to two orders of magnitude reduction in power dissipation. The results suggest much room to improve power dissipation in nanoscale electronics, towards near-fundamental limits, through the co-design of geometry and materials.

Original language	English
Title of host publication	ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology
DOIs	https://doi.org/10.1109/ICICDT.2012.6232852
State	Published - 2012
Event	IEEE International Conference on Integrated Circuit Design and Technology, ICICDT 2012 - Austin, TX, United States Duration: 30 May 2012 → 1 Jun 2012

Publication series

Name	ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology

Conference

Conference	IEEE International Conference on Integrated Circuit Design and Technology, ICICDT 2012
Country/Territory	United States
City	Austin, TX
Period	30/05/12 → 1/06/12

Keywords

carbon nanotubes
graphene
nanoelectronics
phase change memory
power dissipation

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1109/ICICDT.2012.6232852

Cite this

Serov, A. Y., Li, Z., Grosse, K. L., Liao, A. D., Estrada, D., Bae, M. H., Xiong, F., King, W. P., & Pop, E. (2012). Nanoscale power and heat management in electronics. In ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology Article 6232852 (ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology). https://doi.org/10.1109/ICICDT.2012.6232852

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title = "Nanoscale power and heat management in electronics",

abstract = "Power consumption and heat dissipation are significant challenges in electronics ranging from mobile devices to large data centers. A fundamental examination of energy dissipation in such contexts can lead to orders of magnitude improvements in energy efficiency. We present recent highlights from our work examining power and heat dissipation in nanoscale device geometries, at contacts or interfaces, and when novel materials are involved. For instance, thermal conductivity is significantly reduced in nanostructures due to the role of boundary scattering. However relatively unusual effects such as quasi-ballistic and thermoelectric transport could be used to partially mitigate the heat generated during device operation. In addition, careful low-power device design from the outset can alleviate heat dissipation problems before they begin. For example, data storage based on phase-change (rather than charge) with carbon nanotube electrodes can lead to two orders of magnitude reduction in power dissipation. The results suggest much room to improve power dissipation in nanoscale electronics, towards near-fundamental limits, through the co-design of geometry and materials.",

keywords = "carbon nanotubes, graphene, nanoelectronics, phase change memory, power dissipation",

author = "Serov, {Andrey Y.} and Zuanyi Li and Grosse, {Kyle L.} and Liao, {Albert D.} and David Estrada and Bae, {Myung Ho} and Feng Xiong and King, {William P.} and Eric Pop",

year = "2012",

doi = "10.1109/ICICDT.2012.6232852",

language = "English",

isbn = "9781467301466",

series = "ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology",

booktitle = "ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology",

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}

Serov, AY, Li, Z, Grosse, KL, Liao, AD, Estrada, D, Bae, MH, Xiong, F, King, WP & Pop, E 2012, Nanoscale power and heat management in electronics. in ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology., 6232852, ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology, IEEE International Conference on Integrated Circuit Design and Technology, ICICDT 2012, Austin, TX, United States, 30/05/12. https://doi.org/10.1109/ICICDT.2012.6232852

Nanoscale power and heat management in electronics. / Serov, Andrey Y.; Li, Zuanyi; Grosse, Kyle L. et al.
ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology. 2012. 6232852 (ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Li, Zuanyi

AU - Grosse, Kyle L.

AU - Liao, Albert D.

AU - Estrada, David

AU - Bae, Myung Ho

AU - Xiong, Feng

AU - King, William P.

AU - Pop, Eric

PY - 2012

Y1 - 2012

N2 - Power consumption and heat dissipation are significant challenges in electronics ranging from mobile devices to large data centers. A fundamental examination of energy dissipation in such contexts can lead to orders of magnitude improvements in energy efficiency. We present recent highlights from our work examining power and heat dissipation in nanoscale device geometries, at contacts or interfaces, and when novel materials are involved. For instance, thermal conductivity is significantly reduced in nanostructures due to the role of boundary scattering. However relatively unusual effects such as quasi-ballistic and thermoelectric transport could be used to partially mitigate the heat generated during device operation. In addition, careful low-power device design from the outset can alleviate heat dissipation problems before they begin. For example, data storage based on phase-change (rather than charge) with carbon nanotube electrodes can lead to two orders of magnitude reduction in power dissipation. The results suggest much room to improve power dissipation in nanoscale electronics, towards near-fundamental limits, through the co-design of geometry and materials.

AB - Power consumption and heat dissipation are significant challenges in electronics ranging from mobile devices to large data centers. A fundamental examination of energy dissipation in such contexts can lead to orders of magnitude improvements in energy efficiency. We present recent highlights from our work examining power and heat dissipation in nanoscale device geometries, at contacts or interfaces, and when novel materials are involved. For instance, thermal conductivity is significantly reduced in nanostructures due to the role of boundary scattering. However relatively unusual effects such as quasi-ballistic and thermoelectric transport could be used to partially mitigate the heat generated during device operation. In addition, careful low-power device design from the outset can alleviate heat dissipation problems before they begin. For example, data storage based on phase-change (rather than charge) with carbon nanotube electrodes can lead to two orders of magnitude reduction in power dissipation. The results suggest much room to improve power dissipation in nanoscale electronics, towards near-fundamental limits, through the co-design of geometry and materials.

KW - carbon nanotubes

KW - graphene

KW - nanoelectronics

KW - phase change memory

KW - power dissipation

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AN - SCOPUS:84864724004

SN - 9781467301466

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BT - ICICDT 2012 - IEEE International Conference on Integrated Circuit Design and Technology

T2 - IEEE International Conference on Integrated Circuit Design and Technology, ICICDT 2012

Y2 - 30 May 2012 through 1 June 2012

ER -

Nanoscale power and heat management in electronics

Abstract

Publication series

Conference

Keywords

UN SDGs

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