On the Modification of Liquid Water Properties under Vibrational Strong Coupling

A computational study of how liquid water properties are modified when the system is coupled with a (model) Fabry-Perot cavity is reported. At this end, the Cavity-Molecular Dynamics approach proposed recently (Li et al., Proc. Nat. Acad. Sci. USA, 2020, 117, 18324-18331) is employed. This formalism uses a fully atomistic representation of liquid water, which is able to mimic key features of light-matter hybridization under vibrational strong coupling (VSC). The cavity frequency was set to different frequencies, and in particular, following the IR spectrum of liquid water: high frequency (corresponding to O-H stretching modes), medium frequency (corresponding to water molecule bending) and low frequencies (corresponding to librational modes of liquid water). First, the splitting of the infrared spectrum and no visible effect of the cavity on the radial distribution function are confirmed. Second, an effect on the dielectric constant is found when the cavity is resonant with librational modes. Finally, we notice an interesting effect on some dynamical properties, like the diffusion coefficient and the hydrogen bond jumping time. Notably, this effect is strongly dependent on which vibrational mode the cavity is in resonance with.