Abstract
Water boiling control evolution of natural geothermal systems is widely exploited in industrial processes due to the unique non-linear thermophysical behavior. Even though the properties of water both in the liquid and gas state have been extensively studied experimentally and by numerical simulations, there is still a fundamental knowledge gap in understanding the mechanism of the heterogeneous nucleate boiling controlling evaporation and condensation. In this study, the molecular mechanism of bubble nucleation at the hydrophilic and hydrophobic solid–water interface was determined by performing unbiased molecular dynamics simulations using the transition path sampling scheme. Analyzing the liquid to vapor transition path, the initiation of small void cavities (vapor bubbles nuclei) and their subsequent merging mechanism, leading to successively growing vacuum domains (vapor phase), has been elucidated. The molecular mechanism and the boiling nucleation sites’ location are strongly dependent on the solid surface hydrophobicity and hydrophilicity. Then simulations reveal the impact of the surface functionality on the adsorbed thin water molecules film structuring and the location of high probability nucleation sites. Our findings provide molecular-scale insights into the computational aided design of new novel materials for more efficient heat removal and rationalizing the damage mechanisms.
Highlights
Local density fluctuations and a cavity formation with critical bubble size
The transition path sampling (TPS) scheme uses a systematic approach for selecting dynamic trajectories that connect thermodynamic states of the system separated by a large activation barrier without introducing bias due to external driving forces, potential, or reaction c oordinates[19,28]
The density profile obtained for the (001) interface is remarkably different in respect to the (− 111) interface (Fig. S2), indicating, unlike surface functionality
Summary
Local density fluctuations and a cavity formation with critical bubble size. close to solid interfaces, the fluid properties radically change due to repulsive and attractive interactions based on the interface’s hydrophobic/ hydrophilic functionality. The simulations provide insight into the effect of hydrophilic and hydrophobic interactions on the boiling mechanism, the formation of a thin molecular film of adsorbed water at fluid vapor interface and the nature of the vapor nucleation surface sites controlling.
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