Heat capacities of H2O+H2O2, and H2O+N2H4, binary solutions: Isolation of a singular component for C p of supercooled water

Abstract

In an effort to examine further the suggestion that anomalies in the properties of supercooled water reflect the approach to a thermodynamic singularity in the vicinity of −45 °C, an attempt has been made to separate the total heat capacity of water into ’’anomalous’’ and ’’normal’’ components. The basis for such a separation used here is extrapolation to zero solute content of C_p of binary aqueous solutions from which the low temperature anomalies have disappeared. We have studied two closely related systems based on the second components H₂O₂ and N₂H₄. The low temperature molar C_p isotherms are very unusual. The extrapolations to zero solute of C_p isotherms in the two systems yield similar but not identical ’’normal’’ components for pure water. The corresponding alternative sets of ’’anomalous’’ C_p components vs temperature data, when best‐fitted to the singular point equation C_p(anom)=A (T/T_s−1)^−γ, yield within one degree, the same T_s value, 226 K, and exponents either side of the classical value of unity. When the value γ=1.0 is assigned to the anomalous components of the dilute aqueous H₂O₂ solutions, the best fit T_s values accurately mirror the behavior of the solution homogeneous nucleation temperatures.