Rapid advancements in nanotechnologies for energy conversion and transport applications
urgently require a further understanding of interfacial thermal transport and enhancement of …

The emergence of wide and ultrawide bandgap semiconductors has revolutionized the
advancement of next-generation power, radio frequency, and opto-electronics, paving the …

The demand for thermally conductive but electrically insulating materials has increased
greatly in advanced electronic packaging. To this end, polymer-based composites filled with …

Electronic systems and devices operating at significant power levels demand sophisticated
solutions for heat dissipation. Although materials with high thermal conductivity hold promise …

Controlling heat flow is a key challenge for applications ranging from thermal management
in electronics to energy systems, industrial processing, and thermal therapy. However …

High thermal conductivity electronic materials are critical components for high-performance
electronic and photonic devices as both active functional materials and thermal …

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

As electronic devices advance, there's a critical need for thermal interface materials (TIMs)
with high thermal conductivity and minimal thermal resistance to address thermal dissipation …

Machine learned potentials (MLPs) have been widely employed in molecular dynamics
simulations to study thermal transport. However, the literature results indicate that MLPs …

Interface phonon modes that are generated by several atomic layers at the heterointerface
play a major role in the interface thermal conductance for nanoscale high-power devices …