Interfacial thermal resistance (ITR) is the main obstacle for heat flows from one material to
another. Understanding ITR becomes essential for the removal of redundant heat from fast …

Recent years have seen tremendous progress in the theoretical understanding of quantum
systems driven dissipatively by coupling to different baths at their edges. This was possible …

Thermal transport at the nanoscale level is attracting attention not only because of its
physically interesting features such as the peculiar behavior of phonons due to their …

Magnon-phonon scattering (MPS) has attracted widespread attention in quantum heat/spin
transport across the ferromagnetic/nonmagnetic (F/N) interfaces, with the rapid progress of …

The tight-binding method is an effective way to study topological insulators. However, an
intrinsic element, ie, the acoustic sum rule (ASR) in phonon systems, has often been …

Graphene and MoS 2 are two well-known quasi two-dimensional materials. This review
presents a comparative survey of the complementary lattice dynamical and mechanical …

Thermal conductivity of homogeneous twisted stacks of graphite is found to strongly depend
on the misfit angle. The underlying mechanism relies on the angle dependence of phonon …

In recent years,(big) data science has emerged as the “fourth paradigm” in physical science
research. Data-driven techniques, eg machine learning, are advantageous in dealing with …

Recently, there has been increasing interest in phonon thermal transport in low-dimensional
materials, due to the crucial importance of dissipating and managing heat in micro-and nano …

Markovian master equations provide a versatile tool for describing open quantum systems
when memory effects of the environment may be neglected. As these equations are of an …