Spatially-Resolved Phonon Hydrodynamic Flow from First Principles

Material hydrodynamic regimes are characterized by numerous scattering events, each of which conserves quasi-momentum and thus doesn’t oppose the flow of carriers. Recent observations of non-resistive carrier transport in two-dimensional materials suggest that hydrodynamic flow can occur over a wide range of temperatures¹. In thermal transport, hydrodynamic flow manifests itself in two separate phenomena: the wavelike propagation of heat, termed second sound, and parabolic heat profiles, reminiscent of classical incompressible fluid pipe flow.
Theoretical efforts to characterize and predict such phenomena are often restricted to momentum-space, effectively assuming spatial homogeneity. However, hydrodynamic flow exhibits strong real-space signatures. In this talk, we extend previous work and solve the phonon Boltzmann Transport Equation using both spatial and momentum resolution². We present ab initio calculations of hydrodynamic phenomena in real-space in experimentally-realizable geometries.
¹S. Huberman, R. A. Duncan, K. A. Nelson, et. al, Science 26 (2019)
²G. Varnavides, A. S. Jermyn, P. Anikeeva, and P. Narang, Phys. Rev. B 100, 115402 (2019).