Continuous condensation in nanogrooves
Abstract
We consider condensation in a capillary groove of width and depth , formed by walls that are completely wet (contact angle ), which is in a contact with a gas reservoir of the chemical potential . On a mesoscopic level, the condensation process can be described in terms of the midpoint height of a meniscus formed at the liquid-gas interface. For macroscopically deep grooves (), and in the presence of long-range (dispersion) forces, the condensation corresponds to a second order phase transition, such that as where is the chemical potential pertinent to capillary condensation in a slit pore of width . For finite values of , the transition becomes rounded and the groove becomes filled with liquid at a chemical potential higher than with a difference of the order of . For sufficiently deep grooves, the meniscus growth initially follows the power-law but this behaviour eventually crosses over to above , with a gap between the two regimes shown to be . Right at , when the groove is only partially filled with liquid, the height of the meniscus scales as . Moreover, the chemical potential (or pressure) at which the groove is half-filled with liquid exhibits a non-monotonic dependence on with a maximum at and coincides with when . Finally, we show that condensation in finite grooves can be mapped on the condensation in capillary slits formed by two asymmetric (competing) walls a distance apart with potential strengths depending on .
Cite
@article{arxiv.1805.03408,
title = {Continuous condensation in nanogrooves},
author = {Alexandr Malijevský},
journal= {arXiv preprint arXiv:1805.03408},
year = {2018}
}