Continuous condensation in nanogrooves

Malijevský, Alexandr

doi:10.1103/physreve.97.052804

Cited by 4 publications

(3 citation statements)

References 29 publications

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“…[33] and explicit mapping between the two systems has been made in Ref. [58]. Following this analogy one expects that a localizationdelocalization first-order transition occurs along the capillary liquid-gas equilibrium line, i.e.…”

Section: Shallow Groovesmentioning

confidence: 99%

Filling, depinning, unbinding: Three adsorption regimes for nanocorrugated substrates

Malijevský

2020

Phys. Rev. E

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We study adsorption at periodically corrugated substrates formed by scoring rectangular grooves into a planar solid wall which interacts with the fluid via long-range (dispersion) forces. The grooves are assumed to be macroscopically long but their depth, width and separations can all be molecularly small. We show that the entire adsorption process can be divided into three parts consisting of (i) filling the grooves by a capillary liquid; (ii) depinning of the liquid-gas interface from the wall edges; and (iii) unbinding of the interface from the top of the wall, which is accompanied by a rapid but continuous flattening of its shape. Using a nonlocal density functional theory and mesoscopic interfacial models all the regimes are discussed in some detail to reveal the complexity of the entire process and subtle aspects that affect its behaviour. In particular, it is shown that the nature of the depinning phenomenon is governed by the width of the wall pillars (separating grooves), whilst the grooves width only controls the location of the depinning first-order transition, if present.

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Section: Shallow Groovesmentioning

confidence: 99%

Filling, depinning, unbinding: Three adsorption regimes for nanocorrugated substrates

Malijevský

2020

Phys. Rev. E

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“…Wetting and nonwetting behavior of adsorbates on nonporous substrates has attracted much attention from scientists and engineers. − Early studies on model porous systems include those of Evans and co-workers who pioneered density functional theory and applied it to model systems based on the Yukawa potential model. These calculations identified nonwetting, prewetting, and wetting transitions in both slit and cylindrical pores and their associated demarcation temperature zones in T –μ phase diagrams for different values of D *. − Gatica et al studied wetting, prewetting, and capillary condensation transitions in pores with slab geometry, employing a very simple model, and were able to produce D * versus pore width phase diagrams delineating these transitions. − …”

Section: Introductionmentioning

confidence: 99%

Interplay between Wetting and Filling of Argon Adsorption in Slit Pores with Different Surface Energies Transition from Filling in Micropores to Capillary Condensation in Mesopores

Tan

Prasetyo

Dang

et al. 2019

Ind. Eng. Chem. Res.

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to describe the adsorption in pores having widths of less than 1.5 nm at temperatures less than the bulk critical point temperature. In mesopores, another phenomenon, capillary condensation to a liquidlike adsorbate, or "condensate", occurs (Do, D. D. Adsorption Analysis: Equilibria and Kinetics; World Scientific: London, 1983). The distinction between micropore filling and capillary condensation is not unambiguous. It is implicitly assumed in the literature that there is a strong attraction between the adsorbent and a given adsorbate, resulting in the formation of an adsorbed film which thickens as pressure increases. As the pressure approaches the bulk coexistence pressure, the adsorbed film on a planar surface becomes infinitely thick, a feature known as (complete) wetting. In this work, we provide a clear distinction between filling and condensation and also show how wetting behavior (nonwetting/partial wetting/continuous wetting) affects filling and condensation in slit pores and determine conditions under which filling occurs even when the surfaces are nonwetting or partial wetting. We have carried out extensive simulations of argon adsorption in slit pores to investigate the effects of substrate strength, pore size, and temperature on the transition from nonfilling to filling and condensation. From the analysis of the simulation results, we define filling as the phenomenon whereby a pore is filled before the formation of an adsorbate layer on the surface and capillary condensation as one in which adsorbate layers are formed on the pore walls prior to condensation. A parametric map or phase diagram of wetting/filling is constructed to show the interplay between the adsorbent strength, temperature, and pore size, which delineates the various regions of filling and capillary condensation.

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“…These calculations identified non-wetting, prewetting and wetting transitions in both slit and cylindrical pores, and their associated demarcation temperature zones in T- phase diagrams for different values of D* [58][59][60][61]. Gatica et al studied wetting, prewetting and capillary condensation transitions in pores with slab geometry, employing a very simple model, and were able to produce D* versus pore width phase diagrams delineating these transitions [62][63][64][65].…”

Section: Wetting and Non-wettingmentioning

confidence: 99%

Development and application of kinetic Monte Carlo for the simulation of bulk fluids and gaseous adsorption

Tan¹

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Adsorption of gases on solid adsorbents have attracted great interest in its potential applications in chemical and biochemical industries because its process is more economical than many traditional separation or purification processes, such as absorption and distillation. For it to have greater acceptance and wider applications, a good fundamental understanding of the mechanism of adsorption is important to tailor the adsorbent and eventual design of an adsorption process. To this

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Continuous condensation in nanogrooves

Cited by 4 publications

References 29 publications

Filling, depinning, unbinding: Three adsorption regimes for nanocorrugated substrates

Filling, depinning, unbinding: Three adsorption regimes for nanocorrugated substrates

Interplay between Wetting and Filling of Argon Adsorption in Slit Pores with Different Surface Energies Transition from Filling in Micropores to Capillary Condensation in Mesopores

Development and application of kinetic Monte Carlo for the simulation of bulk fluids and gaseous adsorption

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