Heat Conduction in a Three-Dimensional Momentum-Conserving Anharmonic Lattice

Lei Wang; Dahai He; Bambi Hu

doi:10.1103/PhysRevLett.105.160601

Heat Conduction in a Three-Dimensional Momentum-Conserving Anharmonic Lattice

Lei Wang^*, Dahai He, Bambi Hu

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › peer-review

34 Citations (Scopus)

Abstract

Heat conduction in three-dimensional anharmonic lattices was numerically studied by the Green-Kubo theory. For a given lattice width W, a dimensional crossover is generally observed to occur at a W-dependent threshold of the lattice length. Lattices shorter than W will display a 3D behavior while lattices longer than W will display a 1D behavior. In the 3D regime, the heat current autocorrelation function was found to show a power-law decay as a function of the time lag τ as τβ with β=-1.2. This indicates normal heat conduction. However, the decay exponent deviates significantly from the conventional theoretical value of β=-1.5. A flat power spectrum S(ω) of the global heat current in the low-frequency limit was also observed in the 3D regime. This provides not only an alternative verification of normal heat conduction but also a clear physical insight into its origin.

Original language	English
Article number	160601
Number of pages	4
Journal	Physical Review Letters
Volume	105
Issue number	16
Early online date	14 Oct 2010
DOIs	https://doi.org/10.1103/PhysRevLett.105.160601
Publication status	Published - 15 Oct 2010

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title = "Heat Conduction in a Three-Dimensional Momentum-Conserving Anharmonic Lattice",

abstract = "Heat conduction in three-dimensional anharmonic lattices was numerically studied by the Green-Kubo theory. For a given lattice width W, a dimensional crossover is generally observed to occur at a W-dependent threshold of the lattice length. Lattices shorter than W will display a 3D behavior while lattices longer than W will display a 1D behavior. In the 3D regime, the heat current autocorrelation function was found to show a power-law decay as a function of the time lag τ as τβ with β=-1.2. This indicates normal heat conduction. However, the decay exponent deviates significantly from the conventional theoretical value of β=-1.5. A flat power spectrum S(ω) of the global heat current in the low-frequency limit was also observed in the 3D regime. This provides not only an alternative verification of normal heat conduction but also a clear physical insight into its origin.",

author = "Lei Wang and Dahai He and Bambi Hu",

note = "We thank A. Dhar, B. Li, and K. Saito for insightful discussions. L. W. acknowledges the support of the National Natural Science Foundation of China under Grant No. 10874243. We would like to thank the High Performance Cluster Computing Centre at Hong Kong Baptist University for using its computing facilities. Publisher copyright: {\textcopyright} 2010 The American Physical Society",

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doi = "10.1103/PhysRevLett.105.160601",

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AU - Wang, Lei

AU - He, Dahai

AU - Hu, Bambi

N1 - We thank A. Dhar, B. Li, and K. Saito for insightful discussions. L. W. acknowledges the support of the National Natural Science Foundation of China under Grant No. 10874243. We would like to thank the High Performance Cluster Computing Centre at Hong Kong Baptist University for using its computing facilities. Publisher copyright: © 2010 The American Physical Society

PY - 2010/10/15

Y1 - 2010/10/15

N2 - Heat conduction in three-dimensional anharmonic lattices was numerically studied by the Green-Kubo theory. For a given lattice width W, a dimensional crossover is generally observed to occur at a W-dependent threshold of the lattice length. Lattices shorter than W will display a 3D behavior while lattices longer than W will display a 1D behavior. In the 3D regime, the heat current autocorrelation function was found to show a power-law decay as a function of the time lag τ as τβ with β=-1.2. This indicates normal heat conduction. However, the decay exponent deviates significantly from the conventional theoretical value of β=-1.5. A flat power spectrum S(ω) of the global heat current in the low-frequency limit was also observed in the 3D regime. This provides not only an alternative verification of normal heat conduction but also a clear physical insight into its origin.

AB - Heat conduction in three-dimensional anharmonic lattices was numerically studied by the Green-Kubo theory. For a given lattice width W, a dimensional crossover is generally observed to occur at a W-dependent threshold of the lattice length. Lattices shorter than W will display a 3D behavior while lattices longer than W will display a 1D behavior. In the 3D regime, the heat current autocorrelation function was found to show a power-law decay as a function of the time lag τ as τβ with β=-1.2. This indicates normal heat conduction. However, the decay exponent deviates significantly from the conventional theoretical value of β=-1.5. A flat power spectrum S(ω) of the global heat current in the low-frequency limit was also observed in the 3D regime. This provides not only an alternative verification of normal heat conduction but also a clear physical insight into its origin.

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Heat Conduction in a Three-Dimensional Momentum-Conserving Anharmonic Lattice

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