English

Seeding Method for Ice Nucleation under Shear

Computational Physics 2020-08-07 v2 Soft Condensed Matter

Abstract

Hydrodynamic flow can have complex and far-reaching consequences on the rate of homogenous nucleation. We present a general formalism for calculating the nucleation rates of simply sheared systems. We have derived an extension to the conventional Classical Nucleation Theory, explicitly embodying the shear rate. Seeded Molecular Dynamics simulations form the backbone of our approach. The framework can be used for moderate supercoolings, at which temperatures brute-force methods are practically infeasible. The competing energetic and kinetic effects of shear arise naturally from the equations. We show how the theory can be used to identify shear regimes of ice nucleation behaviour for the mW water model, unifying disparate trends reported in the literature. At each temperature, we define a crossover shear rate in the limit of 100010,000 s11000-10,000 \ s^{-1}, beyond which the nucleation rate increases steadily upto a maximum, at the optimal shear rate. For 235235, 240240, 255255 and 260 K260 \ K, the optimal shear rates are in the range of 106107 s1\approx 10^6-10^7 \ s^{-1}. For very high shear rates beyond 108 s110^8 \ s^{-1}, nucleation is strongly inhibited. Our results indicate that the shear-dependent nucleation rate curves have a non-monotonic dependence on temperature.

Keywords

Cite

@article{arxiv.2006.14919,
  title  = {Seeding Method for Ice Nucleation under Shear},
  author = {Amrita Goswami and Indranil Saha Dalal and Jayant K. Singh},
  journal= {arXiv preprint arXiv:2006.14919},
  year   = {2020}
}

Comments

17 pages, 7 figures, supporting information PDF

R2 v1 2026-06-23T16:38:53.760Z