The heat dissipation issue has now become one of the most important bottlenecks for power
electronics due to the rapid increase in power density and working frequency. Towards the …

Atomistic simulation methods, including anharmonic lattice dynamics combined with the
Boltzmann transport equation, equilibrium and non-equilibrium molecular dynamics …

Energy transfer in small nano-sized systems can be very different from that in their
macroscopic counterparts due to reduced dimensionality, interaction with surfaces, disorder …

Over the past few decades, significant progress has been made in micro-and nanoscale
heat transfer. Numerous computational methods have been developed to quantitatively …

Defect scattering is well known to suppress thermal transport. In this study, however, we
perform both molecular dynamics and Boltzmann transport equation calculations, to …

The efficient and economical exploitation of polymers with high thermal conductivity (TC) is
essential to solve the issue of heat dissipation in organic devices. Currently, the …

Understanding thermal transport at the submicron scale is crucial for engineering
applications, especially in the thermal management of electronics and tailoring the thermal …

This work investigates interfacial thermal transport in phononic‐mismatched
heterostructures that consists of pristine black phosphorene and its phononic crystal. It is …

The coherent quantum effect has become increasingly important in the heat dissipation
bottleneck of semiconductor nanoelectronics with the characteristic size recently shrinking …

The addition of nanoparticles to a base fluid (ie, nanofluids) is an effective strategy to
achieve a higher thermal conductivity of a fluid. In a common nanofluid, the suspended …