Fluctuations of local electric field and dipole moments in water between metal walls

Abstract

We examine the thermal fluctuations of the local electric field Ek loc and the dipole moment μk in liquid water at T=298 K between metal walls in electric field applied in the perpendicular direction. We use analytic theory and molecular dynamics simulation. In this situation, there is a global electrostatic coupling between the surface charges on the walls and the polarization in the bulk. Then, the correlation function of the polarization density pz(r) along the applied field contains a homogeneous part inversely proportional to the cell volume V. Accounting for the long-range dipolar interaction, we derive the Kirkwood-Frohlich formula for the polarization fluctuations when the specimen volume v is much smaller than V. However, for not small v/V, the homogeneous part comes into play in dielectric relations. We also calculate the distribution of Ek loc in applied field. As a unique feature of water, its magnitude |Ek loc| obeys a Gaussian distribution with a large mean value E0 17~V/nm, which arises mainly from the surrounding hydrogen-bonded molecules. Since |μk|E0 30 k BT, μk becomes mostly parallel to Ek loc. As a result, the orientation distributions of these two vectors nearly coincide, assuming the classical exponential form. In dynamics, the component of μk(t) parallel to Ek loc(t) changes on the timescale of the hydrogen bonds 5 ps, while its smaller perpendicular component undergoes librational motions on timescales of 0.01 ps.