Controllable Fermi-liquid to Dirac-fluid crossover at room temperature.

Beyond the commonly known diffusive and ballistic transport regimes, where charges either move randomly or in a straight line, a hydrodynamic regime exists where strong interactions lead to fluid-like, collective motion of charges. The restrictive conditions for reaching this hydrodynamic regime have recently been satisfied experimentally in two-dimensional electron systems. Here, by performing thermoelectric microscopy with femtosecond temporal and sub-100 nm spatial control, we show that this hydrodynamic regime persists at room temperature. In particular, we demonstrate the ability to tune graphene electrons between the Fermi-liquid and the quantum-critical Dirac-fluid regime, by controlling the electron temperature and Fermi energy. Upon approaching charge neutrality, the thermal diffusivity of the Dirac fluid is more than two orders of magnitude larger than its non-interacting counterpart.