Add to ORKGAnisotropic solids possess thermal conductivities ranging from among the highest found in nature, as in the in-plane thermal conductivity of graphite, to the lowest, as in the cross-plane thermal conductivity of disordered layered crystals. Though these extremes of thermal conductivity make anisotropic materials attractive for diverse applications such as thermal management and thermal insulation, the microscopic physics of heat conduction in these materials remain poorly understood. In this review article, we discuss the recent advances in our understanding of thermal phonon transport in anisotropic solids obtained using new theoretical, computational, and experimental tools
Various modern devices involve highly anisotropic materials. For example, Bi2Te3 is used in thermoel...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
The thermal properties of anisotropic crystals are of both fundamental and practical interest, but t...
The thermal properties of anisotropic crystals are of both fundamental and practical interest, but t...
The thermal properties of anisotropic crystals are of both fundamental and practical interest, but t...
Heat conduction by phonons is a ubiquitous process that incorporates a wide range of physics and pla...
Heat conduction by phonons is a ubiquitous process that incorporates a wide range of physics and pla...
We discuss recent advances in the microscopic simulations of thermal conductivity through the prism ...
Abstract: Knowledge of how heat flows anisotropically in van der Waals (vdW) materials is crucial fo...
Thermal conductivity plays a crucial role in many applications; the use of single-crystal and textur...
Thermal conductivity plays a crucial role in many applications; use of single-crystal and texture...
Heat conduction in graphite has been studied for decades because of its exceptionally large thermal ...
Heat conduction in graphite has been studied for decades because of its exceptionally large thermal ...
A comprehensive description of how heat and temperature evolve on nanometer to submicron length-scal...
Various modern devices involve highly anisotropic materials. For example, Bi2Te3 is used in thermoel...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
The thermal properties of anisotropic crystals are of both fundamental and practical interest, but t...
The thermal properties of anisotropic crystals are of both fundamental and practical interest, but t...
The thermal properties of anisotropic crystals are of both fundamental and practical interest, but t...
Heat conduction by phonons is a ubiquitous process that incorporates a wide range of physics and pla...
Heat conduction by phonons is a ubiquitous process that incorporates a wide range of physics and pla...
We discuss recent advances in the microscopic simulations of thermal conductivity through the prism ...
Abstract: Knowledge of how heat flows anisotropically in van der Waals (vdW) materials is crucial fo...
Thermal conductivity plays a crucial role in many applications; the use of single-crystal and textur...
Thermal conductivity plays a crucial role in many applications; use of single-crystal and texture...
Heat conduction in graphite has been studied for decades because of its exceptionally large thermal ...
Heat conduction in graphite has been studied for decades because of its exceptionally large thermal ...
A comprehensive description of how heat and temperature evolve on nanometer to submicron length-scal...
Various modern devices involve highly anisotropic materials. For example, Bi2Te3 is used in thermoel...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...