Thermal Resistance Of A Liquid-Solid Interface on Curved Smooth and Rough Walls

Extended Abstract The breakdown of the momentum transfer at a fluid-solid contact has been known in micro/nanofluidics for many years. Influence of the surface shape (i.e. convex/concave) has been investigated in gas-phase flows [1-2]. On the other hand, thermal boundary resistance is a known phenomenon, which reduces the heat transfer between heterogeneous materials and affects overall thermal performance, has not been investigated sufficiently well at curved interfaces. The present study runs non-equilibrium molecular dynamics (NEMD) simulations and considers a thin heated cylindrical shell, which is located in the middle of the gap between two coaxial stationary cylinders, in order to investigate the thermal boundary resistance. In contrast to previous molecular dynamics simulations [3-4], realistic walls are created to examine the interfacial heat transfer related to the surface curvature over rough and smooth surfaces. The results show the existence of the opposing effect of curvature. This effect demonstrates itself by increasing heat transfer from a hot concave surface to the fluid with curvature, while, in contrast, by decreasing heat transfer from a hot convex surface. At identical curvature and surface area, the present results show that the thermal resistance between a hot convex silver surface and liquid argon is larger than the thermal resistance between a hot concave silver surface and liquid argon. In addition,