Nanostructuring expands thermal limits

被引：141

作者：

Kim, Woochul ^{[1
]}

Wang, Robert

Majumdar, Arun

机构：

[1] Univ Calif Berkeley, Dept Mech Engn, Berkeley, CA 94720 USA

[2] Lawrence Berkeley Natl Lab, Div Mat Sci, Berkeley, CA 94720 USA

来源：

NANO TODAY | 2007年 / 2卷 / 01期

基金：

美国国家科学基金会;

关键词：

D O I：

10.1016/S1748-0132(07)70018-X

中图分类号：

O6 [化学];

学科分类号：

0703 ;

摘要：

Scientists and engineers can exploit nanostructures to manipulate thermal transport in solids. This is possible because the dominant heat carriers in nonmetals - crystal vibrations (or phonons) - have characteristic lengths in the nanometer range. We review research where this approach is used and propose future research directions. For instance, concepts such as phonon filtering, correlated scattering, and waveguiding could expand the extremes of thermal transport in both the insulating and conducting limits. This will have major implications on energy conservation and conversion, information technology, and thermal management systems.

引用

页码：40 / 47

页数：8

共 69 条

[1] THERMAL-DIFFUSIVITY OF ISOTOPICALLY ENRICHED C-12 DIAMOND [J].

ANTHONY, TR ;

BANHOLZER, WF ;

FLEISCHER, JF ;

WEI, LH ;

KUO, PK ;

THOMAS, RL ;

PRYOR, RW .

PHYSICAL REVIEW B, 1990, 42 (02) :1104-1111

[2] Kapitza resistance at the liquid-solid interface [J].

Barrat, JL ;

Chiaruttini, F .

MOLECULAR PHYSICS, 2003, 101 (11) :1605-1610

[3] Unusually high thermal conductivity of carbon nanotubes [J].

Berber, S ;

Kwon, YK ;

Tománek, D .

PHYSICAL REVIEW LETTERS, 2000, 84 (20) :4613-4616

[4] CRYSTAL DYNAMICS OF LEAD .1. DISPERSION CURVES AT 100 DEGREES K [J].

BROCKHOUSE, BN ;

RAO, KR ;

WOODS, ADB ;

CAGLIOTI, G ;

ARASE, T .

PHYSICAL REVIEW, 1962, 128 (03) :1099-&

[5] Ballistic thermal and electrical conductance measurements on individual multiwall carbon nanotubes [J].

Brown, E ;

Hao, L ;

Gallop, JC ;

Macfarlane, JC .

APPLIED PHYSICS LETTERS, 2005, 87 (02)

[6] Nanoscale thermal transport [J].

Cahill, DG ;

Ford, WK ;

Goodson, KE ;

Mahan, GD ;

Majumdar, A ;

Maris, HJ ;

Merlin, R ;

Phillpot, SR .

JOURNAL OF APPLIED PHYSICS, 2003, 93 (02) :793-818

[7] Interface thermal conductance and the thermal conductivity of multilayer thin films [J].

Cahill, DG ;

Bullen, A ;

Lee, SM .

HIGH TEMPERATURES-HIGH PRESSURES, 2000, 32 (02) :135-142

[8] Thermometry and thermal transport in micro/nanoscale solid-state devices and structures [J].

Cahill, DG ;

Goodson, KE ;

Majumdar, A .

JOURNAL OF HEAT TRANSFER-TRANSACTIONS OF THE ASME, 2002, 124 (02) :223-241

[9] Thermal-conductivity measurements of GaAs/AlAs superlattices using a picosecond optical pump-and-probe technique [J].

Capinski, WS ;

Maris, HJ ;

Ruf, T ;

Cardona, M ;

Ploog, K ;

Katzer, DS .

PHYSICAL REVIEW B, 1999, 59 (12) :8105-8113

[10] Isotope effect on the thermal conductivity of boron nitride nanotubes [J].

Chang, C. W. ;

Fennimore, A. M. ;

Afanasiev, A. ;

Okawa, D. ;

Ikuno, T. ;

Garcia, H. ;

Li, Deyu ;

Majumdar, A. ;

Zettl, A. .

PHYSICAL REVIEW LETTERS, 2006, 97 (08)

← 1 2 3 4 5 6 7 →