Viscosity and Stokes-Einstein relation in deeply supercooled water under pressure.

Abstract

We report measurements of the shear viscosity η in water up to 150MPa and down to 229.5K. This corresponds to more than 30K supercooling below the melting line. The temperature dependence is non-Arrhenius at all pressures, but its functional form at 0.1MPa is qualitatively different from that at all pressures above 20MPa. The pressure dependence is non-monotonic, with a pressure-induced decrease of viscosity by more than 50% at low temperature. Combining our data with literature data on the self-diffusion coefficient Ds of water, we check the Stokes-Einstein relation which, based on hydrodynamics, predicts constancy of Dsη/T, where T is the temperature. The observed temperature and pressure dependence of Dsη/T is analogous to that obtained in simulations of a realistic water model. This analogy suggests that our data are compatible with the existence of a liquid-liquid critical point at positive pressure in water.