润湿
材料科学
化学物理
氢键
氧化物
四面体
氢
表面粗糙度
分子动力学
密度泛函理论
曲面(拓扑)
接触角
表面光洁度
纳米技术
催化作用
结晶学
氧化铝
复合氧化物
化学工程
溶剂化壳
平方(代数)
自组装
作者
Venkata Surya Kumar Choutipalli,Michael L. Klein,Mark DelloStritto
摘要
Despite advances in understanding macroscopic wetting behavior, the atomistic mechanisms underlying hydrophilicity at solid-liquid interfaces remain only partially understood, particularly for chemically and structurally complex surfaces. Alumina, a widely used oxide in catalysis and surface coatings, exhibits such complexity due to the variability in surface termination and hydroxylation. In this study, we investigate the hydrophilicity of three crystallographic terminations of hydroxylated alumina-(0001), (1120), and (0112)-using molecular dynamics simulations based on neural network potential trained on density functional theory data. We quantify hydrophilicity through mean square displacement, density fluctuations, hydrogen bonding characteristics, vibrational density of states, the tetrahedral order parameter, and the contact angle. Our results reveal a clear hydrophilicity trend of (1120) < (0001) < (0112), with the relatively flat surface (1120) showing the least structured interfacial water and the corrugated surface (0112) showing the most pronounced confinement and hydrogen bonding. This trend is reflected in reduced water mobility, suppressed density fluctuations, stronger surface-to-water hydrogen bonds, and greater disruption of tetrahedral order near the (0112) interface. These findings demonstrate that atomic-scale surface roughness and the degree to which it can disrupt the structure of water are key to forming strong surface-to-water hydrogen bonds, thereby offering a microscopic rationale for hydrophilic behavior at oxide surfaces.
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