Quantum thermal transport in nanostructures

TL;DR

This review discusses quantum theoretical methods for calculating thermal transport in nanostructures, emphasizing Green's function techniques, nonlinear effects, and recent experimental developments.

Contribution

It provides a comprehensive overview of atomistic quantum models and introduces new computational algorithms for phonon transport in nanojunctions.

Findings

Derivation of Landauer formula for ballistic phonon transport

Development of iterative and eigenvalue algorithms for surface Green's functions

Discussion of nonlinear effects and recent experimental results

Abstract

In this colloquia review we discuss methods for thermal transport calculations for nanojunctions connected to two semi-infinite leads served as heat-baths. Our emphases are on fundamental quantum theory and atomistic models. We begin with an introduction of the Landauer formula for ballistic thermal transport and give its derivation from scattering wave point of view. Several methods (scattering boundary condition, mode-matching, Piccard and Caroli formulas) of calculating the phonon transmission coefficients are given. The nonequilibrium Green's function (NEGF) method is reviewed and the Caroli formula is derived. We also give iterative methods and an algorithm based on a generalized eigenvalue problem for the calculation of surface Green's functions, which are starting point for an NEGF calculation. A systematic exposition for the NEGF method is presented, starting with the fundamental definitions of the Green's functions, and ending with equations of motion for the contour ordered Green's functions and Feynman diagrammatic expansion. In the later part, we discuss the treatments of nonlinear effects in heat conduction, including a phenomenological expression for the transmission, NEGF for phonon-phonon interactions, molecular dynamics (generalized Langevin) with quantum heat-baths, and electron-phonon interactions. Some new results are also shown. We also briefly review the experimental status of the thermal transport measurements in nanostructures.