We present a general framework for studying strongly coupled radiative and conductive heat
transfer between arbitrarily shaped bodies separated by subwavelength distances. Our …

We describe a recently developed formulation of coupled conductive and radiative heat
transfer (RHT) between objects separated by nanometric, vacuum gaps. Our results rely on …

We study the interplay of conductive and radiative heat transfer (RHT) in planar geometries
and predict that temperature gradients induced by radiation can play a significant role on the …

Near-field radiative heat transfer exhibits various effects, such as amplification due to the
geometry of the system. In this work, we construct a periodic layered structure which consists …

We describe a fluctuating-surface-current formulation of radiative heat transfer, applicable to
arbitrary geometries in both the near and far field, that directly exploits efficient and …

Systems of many nanoparticles or volume-discretized bodies exhibit collective radiative
properties that could be used for enhanced, guided, or tunable thermal radiation. These are …

In the theory of radiative heat exchanges between two closely spaced bodies introduced by
Polder and van Hove, no interplay between the heat carriers inside the materials and the …

In chains of closely spaced nanoparticles supporting surface polaritons, near-field
electromagnetic coupling leads to collective effects and super-Planckian thermal radiation …

In this work, we study thermalization between two bodies separated by a vacuum gap by
coupling the non-Fourier behavior of the materials with the radiative heat transfer in the near …

In a previous Letter, we derived fundamental limits to radiative heat transfer applicable in
near-through far-field regimes, based on the choice of material susceptibilities and bounding …