Molecular dynamics simulations of the effect of static electric field on progressive ice formation

电场 冰晶 分子动力学 偶极子 无定形冰 材料科学 化学物理 凝聚态物理 化学 物理 结晶学 光学 无定形固体 计算化学 量子力学 有机化学
作者
Ruiqi Shang,Tongyu Wu,S. A. Meguid
出处
期刊:Journal of Chemical Physics [American Institute of Physics]
卷期号:161 (9) 被引量:3
标识
DOI:10.1063/5.0226624
摘要

Ice accumulation under static electric fields presents a significant hazard to transmission lines and power grids. Contemporary computational studies of electrofreezing predominantly probed excessive electric fields (109 V/m) that are significantly higher than those typically encountered in proximity to transmission lines. To elucidate the influence of realistic electric fields (105 V/m) on ice crystallization, we run extensive molecular dynamics (MD) simulations across dual ice–water coexistence systems. Three aspects of work were accordingly examined. First, we investigated the influence of the effect of static electric fields, with a strength of 105 V/m, along three orthogonal axes on the phase transition during the encountered freezing and melting processes. Second, we established the mechanism of how the direction of an electric field, the initial ice crystallography, and the adjacent crystal planes influence the solidification process. Third, the results of our MD simulations were further post-processed to determine the dipole moment, radial distribution, and angle distribution resulting from the static electric field. Our results indicate that while weak electric fields do not cause complete polarization of liquid water molecules, they can induce a transition to a more structured ice-like geometry of the water molecules at the ice–water interphase region, particularly when applied perpendicular to the ice–water interphase. Notably, the interface adjacent to cubic ice exhibits a greater response to the electric fields than that adjacent to hexagonal ice. This is attributable to the intrinsic differences in their original hydrogen bonding networks.
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