Add to ORKGWe introduce a novel approach to model heat transport in solids, based on the Green-Kubo theory of linear response. It naturally bridges the Boltzmann kinetic approach in crystals and the Allen-Feldman model in glasses, leveraging interatomic force constants and normal-mode linewidths computed at mechanical equilibrium. At variance with molecular dynamics, our approach naturally and easily accounts for quantum mechanical effects in energy transport. Our methodology is carefully validated against results for crystalline and amorphous silicon from equilibrium molecular dynamics and, in the former case, from the Boltzmann transport equation
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
With significant recent advancements in thermal sciences—such as the development of new theoretical ...
Thermal conductivity is a key parameter in designing high performance thermoelectric materials. A mu...
We introduce a novel approach to model heat transport in solids, based on the Green-Kubo theory of l...
We introduce a novel approach to model heat transport in solids, based on the Green-Kubo theory of l...
Understanding heat transport in semiconductors and insulators is of fundamental importance because o...
The simulation of heat transport and the estimation of thermal conductivity in glasses is of crucial...
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)...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
Crystals and glasses exhibit fundamentally different heat conduction mechanisms: the periodicity of ...
Using harmonic and anharmonic force constants extracted from density functional calculations within ...
Thermal conductivity in dielectric crystals is the result of the relaxation of lattice vibrations de...
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
With significant recent advancements in thermal sciences—such as the development of new theoretical ...
Thermal conductivity is a key parameter in designing high performance thermoelectric materials. A mu...
We introduce a novel approach to model heat transport in solids, based on the Green-Kubo theory of l...
We introduce a novel approach to model heat transport in solids, based on the Green-Kubo theory of l...
Understanding heat transport in semiconductors and insulators is of fundamental importance because o...
The simulation of heat transport and the estimation of thermal conductivity in glasses is of crucial...
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)...
Atomic-level thermal transport is explored using lattice dynamics theory and molecular dynamics (MD)...
Crystals and glasses exhibit fundamentally different heat conduction mechanisms: the periodicity of ...
Using harmonic and anharmonic force constants extracted from density functional calculations within ...
Thermal conductivity in dielectric crystals is the result of the relaxation of lattice vibrations de...
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
Demands for engineering thermal transport properties are ever increasing for a wide range of modern ...
With significant recent advancements in thermal sciences—such as the development of new theoretical ...
Thermal conductivity is a key parameter in designing high performance thermoelectric materials. A mu...