Journal of Molecular Liquids | 2021
Thermodynamics of cavity formation in different solvents: Enthalpy, entropy, and the solvophobic effects
Abstract
Abstract For a long time thermodynamics of cavity formation in non-aqueous solvents remained virtually unexplored. We evaluated the entropic and enthalpic contributions into the Gibbs free energy of cavity formation in 22 structurally different organic solvents and water at 298\xa0K. The calculations were carried out using 50–100\xa0ns long molecular dynamics trajectories of solvents and Widom test particle insertion method with up to 1011 insertions per trajectory. It is shown that protic solvents with three-dimensional hydrogen bond networks, namely water, formamide, glycerol, ethylene glycol, propylene glycol, and diethylene glycol, behave differently from other considered solvents. They are characterized with lower values of the entropy of cavity formation than other considered solvents, which also leads to the higher Gibbs free energies. Water has a particularly low entropy as well as the lowest enthalpy of cavity formation at room temperature. We point out the similar tendencies observed for the thermodynamic functions of the cavities and solvation of real molecules in the considered solvents using entropy vs enthalpy and Gibbs free energy vs enthalpy plots. The cavity term governs the difference in solvation properties of protic hydrogen-bonded and aprotic solvents giving rise to the hydrophobic and more general solvophobic effects.