Two-dimensional phonon transport in graphene

Journal of Physics. Condensed Matter : an Institute of Physics Journal
Denis L Nika, Alexander A Balandin

Abstract

Properties of phonons-quanta of the crystal lattice vibrations-in graphene have recently attracted significant attention from the physics and engineering communities. Acoustic phonons are the main heat carriers in graphene near room temperature, while optical phonons are used for counting the number of atomic planes in Raman experiments with few-layer graphene. It was shown both theoretically and experimentally that transport properties of phonons, i.e. energy dispersion and scattering rates, are substantially different in a quasi-two-dimensional system such as graphene compared to the basal planes in graphite or three-dimensional bulk crystals. The unique nature of two-dimensional phonon transport translates into unusual heat conduction in graphene and related materials. In this review, we outline different theoretical approaches developed for phonon transport in graphene, discuss contributions of the in-plane and cross-plane phonon modes, and provide comparison with available experimental thermal conductivity data. Particular attention is given to analysis of recent results for the phonon thermal conductivity of single-layer graphene and few-layer graphene, and the effects of the strain, defects, and isotopes on phonon transp...Continue Reading

References

Dec 15, 1990·Physical Review. B, Condensed Matter·T AizawaC Oshima
Jul 15, 1990·Physical Review. B, Condensed Matter·T R AnthonyR W Pryor
Jun 6, 1988·Physical Review Letters·E R Cowley
Feb 17, 1992·Physical Review Letters·A P RamirezK B Lyons
Jun 14, 1993·Physical Review Letters·L WeiW F Banholzer
Sep 16, 2000·Physical Review Letters·S BerberD Tomanek
Jun 21, 2001·Physical Review Letters·A Dhar
Dec 12, 2001·Physical Review Letters·P KimP L McEuen
Feb 28, 2002·Physical Review Letters·Lei Yang
Nov 22, 2002·Physical Review Letters·Onuttom Narayan, Sriram Ramaswamy
Mar 5, 2004·Physical Review Letters·J MaultzschP Ordejón
Oct 23, 2004·Science·K S NovoselovA A Firsov
Aug 20, 2005·Journal of Nanoscience and Nanotechnology·Alexander A Balandin
Nov 11, 2005·Nature·K S NovoselovA A Firsov
Jun 29, 2006·Physical Review Letters·Giada BasileStefano Olla
Feb 21, 2008·Nano Letters·Alexander A BalandinChun Ning Lau
Sep 4, 2008·Physical Review Letters·C W ChangA Zettl
Aug 29, 2009·Nano Letters·Xuesong LiRodney S Ruoff
Mar 12, 2010·ACS Nano·Clement FaugerasA K Geim
Apr 7, 2010·Physical Review Letters·Keiji Saito, Abhishek Dhar
Apr 10, 2010·Science·Jae Hun SeolLi Shi
Apr 21, 2010·Nano Letters·Enrique MuñozBoris I Yakobson
May 11, 2010·Nature Materials·Suchismita GhoshAlexander A Balandin
Dec 3, 2010·Nano Letters·Chun Hung LuiTony F Heinz
Dec 17, 2010·Nano Letters·Zhen Wah TanChee Kwan Gan
Feb 12, 2011·Journal of the American Chemical Society·Xuesong LiRodney S Ruoff
Jul 21, 2011·Physical Review Letters·Albert D LiaoEric Pop
Jul 23, 2011·Nature Materials·Alexander A Balandin
Oct 4, 2011·ACS Nano·Chunxiao CongMildred S Dresselhaus
Jan 5, 2012·Nano Letters·Khan M F Shahil, Alexander A Balandin
Jan 11, 2012·Nature Materials·Shanshan ChenRodney S Ruoff

❮ Previous
Next ❯

Citations

May 23, 2012·Nano Letters·Denis L NikaAlexander A Balandin
Jul 26, 2013·Physical Chemistry Chemical Physics : PCCP·Guofeng XieGang Zhang
May 13, 2014·Nanoscale·O FrankM Kalbac
Oct 3, 2014·Nanoscale·Hongyang LiShanshan Chen
Aug 12, 2014·Nano Letters·H MalekpourA A Balandin
Jul 17, 2015·Scientific Reports·Jarosław JudekMariusz Zdrojek
Feb 8, 2013·Scientific Reports·Hâldun SevinçliGianaurelio Cuniberti
Jul 19, 2013·Scientific Reports·Jin-Wu JiangTimon Rabczuk
Mar 13, 2014·Small·Yong XuWenhui Duan
Oct 16, 2015·Scientific Reports·Wu-Xing Zhou, Ke-Qiu Chen
Aug 13, 2015·Physical Chemistry Chemical Physics : PCCP·Xiaojian TanHaochuan Jiang
Apr 16, 2015·Physical Chemistry Chemical Physics : PCCP·Lanqing XuYongping Zheng
Mar 7, 2015·Physical Chemistry Chemical Physics : PCCP·Guofeng Xie, Yulu Shen
May 5, 2016·Scientific Reports·Chengru WangBaowen Li
Jul 20, 2016·Nanoscale·Hoda MalekpourAlexander A Balandin
Jul 6, 2014·ACS Nano·Bonil KooElena V Shevchenko
Oct 27, 2016·The Journal of Chemical Physics·Ji-Hang ZouBing-Yang Cao
Oct 21, 2016·Nanoscale·Yang ZhouXin-Gao Gong
Dec 29, 2016·Nano Letters·Jin Hee LeeSeong Chu Lim
Mar 31, 2015·Scientific Reports·Hatef SadeghiColin J Lambert
Jun 14, 2017·Nature Communications·Haidong WangJie Chen
Mar 3, 2018·Journal of Physics. Condensed Matter : an Institute of Physics Journal·Xue-Kun ChenKe-Qiu Chen
Mar 6, 2018·Journal of Physics. Condensed Matter : an Institute of Physics Journal·M BaratiM Farmanbar
Feb 6, 2017·Nanotechnology·Gabriela C CorreaZlatan Aksamija
May 29, 2018·Physical Chemistry Chemical Physics : PCCP·Jarosław JudekMariusz Zdrojek
May 29, 2018·Nanoscale·Zhenzhen QinMing Hu
Jul 15, 2015·Beilstein Journal of Nanotechnology·Hatef SadeghiColin J Lambert
Nov 9, 2019·Science Advances·Prashanth S VenkataramAlejandro W Rodriguez
Mar 18, 2015·Journal of Physics. Condensed Matter : an Institute of Physics Journal·Philippe DollfusJérôme Saint-Martin
Feb 18, 2016·Journal of Physics. Condensed Matter : an Institute of Physics Journal·Amjad Al Taleb, Daniel Farías

❮ Previous
Next ❯

Related Concepts

Related Feeds

Cardiac Conduction System

The cardiac conduction system is a specialized tract of myocardial cells responsible for maintaining normal cardiac rhythm. Discover the latest research on the cardiac conduction system here.