Formation of an electron-phonon bi-fluid in bulk antimony

The flow of charge and entropy in solids usually depends on collisions decaying quasiparticle momentum. Hydrodynamic corrections can emerge, however, if most collisions among quasiparticles conserve momentum and the mean-free-path approaches the sample dimensions. Here, through a study of electrical and thermal transport in antimony (Sb) crystals of various sizes, we document the emergence of a two-component fluid of electrons and phonons. Lattice thermal conductivity, dominated by electron scattering down to 0.1 K, displays prominent quantum oscillations. The Dingle mobility does not vary despite an order-of-magnitude change in transport mobility. Electrical resistivity shows an aborted Bloch-Gruneisen behavior, implying momentum conservation of electron-phonon collisions. Taken together, these results draw a consistent picture of a bi-fluid whose shortest intrinsic time scale is defined by momentum-conserving electron-phonon collisions.