Wall-induced phase transition controlled by layering freezing
HJ Zhang and SM Peng and XG Long and XS Zhou and JH Liang and CB Wan and J Zheng and X Ju, PHYSICAL REVIEW E, 89, 032412 (2014).
DOI: 10.1103/PhysRevE.89.032412
Molecular dynamics simulations of the Lennard-Jones model are used to study phase transitions at a smooth surface. Our motivation is the observation that the existence of an attractive wall facilitates crystallization. To investigate how this wall influences phase transitions, the strength of wall-particle interaction is varied in our studies. We find that the phase behavior depends on the strength parameter alpha, i.e., the ratio between wall-particle and the particle- particle attraction strength. Three critical values of the ratio, namely, alpha(p), alpha(w), and alpha(c), are used to define the qualitative nature of the phase behaviors at a smooth surface. Some interesting phenomena due to the increase of alpha are observed. First, a set of close-packed planes, i.e., 111 planes in fcc structures or 0001 planes in hcp structures, are "rotated" from intersecting to parallel to the wall when alpha = alpha(p); second, the layering phase transition close to the wall antecedes that of the bulk when alpha = alpha(w). Finally, the first-order phase transition in the first two layers is supplanted by a continuous phase transition when alpha = alpha(c), which to some extent can be treated as a quasi-two-dimensional process. We find that bulk freezing always discontinuously occurs through a first-order phase transition, and seems to be isolated from the freezing process occurring close to the attractive surfaces. Moreover, during the heating process, we observe minimal dependence at a strongly attractive surface.
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