Paper detail

Lambda-type sharp rise in the widths of Raman and infra-red line shape near the Widom line in super-critical water above its gas-liquid critical temperature

A lambda-type divergent rise of Raman linewidth of liquid nitrogen near its critical temperature has been a subject of many discussions in the past[1-5]. Here we explore the possibility of such an anomaly in infra-red and Raman spectroscopy of super-critical water (SCW) by varying the density across the Widom line just above its critical temperature. Vibrational phase relaxation is expected to be a sensitive probe of fluid dynamics. We carry out computer simulations of two different model potentials (SPC/E and TIP4P/2005) to obtain the necessary time correlation functions. An additional feature of this work is a quantum chemical calculation of the anharmonicity parameter that largely controls frequency fluctuations. We find a sharp rise in the vibrational relaxation rate (or the line widths) for both the models as we travel across the Widom line. The rise is noticeably less sharp in water than in nitrogen. We attribute this difference to the faster relaxation rate in water. We demonstrate that the anomalous rise is due to sharp increase in the mean square frequency fluctuation and not due to any dynamical critical slowing down because the time constant of the normalized frequency-frequency time correlation functions show lack of any noticeable change as we move across the Widom line. We present an explanation of the observed results using the mode coupling theory of liquid dynamics.