T. E. Wetzel scite author profile

T. E. Wetzel

5Publications

43Citation Statements Received

214Citation Statements Given

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171

209

Affiliations

Johns Hopkins University

Publications

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Monte Carlo simulations on the effect of substrate geometry on adsorption and compression

Wetzel

Erickson

Donohue

et al. 2004

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Canonical Monte Carlo simulations were used to study the adsorption and compression of fluid layers on model substrates with cubic, (111) fcc, and graphite geometries. The effect of the relative size of the fluid and substrate molecules on adsorption was considered for strong molecule-surface interactions. In the case of monolayer formation, it was found that the surface geometry and the size of the adsorbate molecules had a significant effect on the structure of the adsorbed layer. These structures varied from well-ordered, commensurate layers to liquid-like structures. Lateral compression was observed for certain fluid to substrate molecule sizes. For the interactions studied in this work, it was found that maximum lateral compression occurred on the cubic surface when adsorbate molecules had a diameter approximately 15% larger than the substrate diameter. In the case of multilayer formation, it was found that second and higher adsorbed layers could compress into the adsorbed layers below them. For cubic substrates, the interlayer compression was predicted analytically with reasonable accuracy, with maximum interlayer compression found for fluid diameters approximately 90% the size of substrate molecule diameters.

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Generalization of Kelvin's equation for compressible liquids in nanoconfinement

Chen

Wetzel

Aranovich

et al. 2006

Journal of Colloid and Interface Science

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Adsorption Behavior of Repulsive Molecules

2005

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Recently, it has been shown that adsorption of gases on solid surfaces often leads to repulsive forces between adsorbate molecules. In this paper, adsorption of molecules on a one-dimensional lattice is considered for repulsive interactions between adsorbate molecules. Exact adsorption isotherms are calculated and analyzed for finite and infinite chains of active sites (i.e., a one-dimensional lattice). Although the mathematical solution for the one-dimensional lattice is known for attractive and repulsive systems, the effects of intermolecular repulsions on adsorption behavior have not been studied in detail previously. Similarly, though the mathematics for the one-dimensional lattice has been solved for any arbitrary lattice length, the effect of finite size on adsorption isotherms for repulsive adsorbate interactions has never been examined. This paper shows that spatial confinement and strong attraction to active sites can cause compression of an adsorbed phase and that repulsive interactions between adsorbed molecules result in steps in the adsorption isotherms. For higher chemical potentials, the density increases until saturating at the lattice capacity. These steps in the adsorption isotherm have not been observed in previous studies of lattice systems. For small lattices, the adsorption behavior was found to be fundamentally different for even and odd values of lattice length. Lattices with an even number of lattice sites can have two steps in the adsorption isotherm, whereas systems with an odd number of sites only have a single step occurring at a coverage slightly greater than half the lattice capacity.

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Monte Carlo simulations of phase transitions and adsorption isotherm discontinuities on surface compression

Charniak¹,

Wetzel²,

Aranovich³

et al. 2008

Journal of Colloid and Interface Science

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Configurational probabilities for monomers, dimers and trimers in fluids

Chen

Wetzel

Aranovich

et al. 2008

Phys. Chem. Chem. Phys.

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A new analytical approach is proposed to model aggregation of molecules with isotropic, nearest-neighbor, attractive interactions. By treating the clustering process as a chain reaction, equations with the exact high temperature limit are derived by evaluating the occupation probabilities of nearest neighbors based on the Ono-Kondo approach for a hexagonal lattice to calculate the configurational probabilities of i-mers (i = 1, 2, 3). Equilibrium constants for dimers and trimers are calculated based on the configurational probability data. The proposed model agrees well with Monte Carlo simulations at medium and high temperatures. At low temperatures, the model can be improved by considering the full set of site densities in the first shell of a central trimer. Approximate analytical solutions derived from exact calculations of the grand partition function for monomer adsorption on a 4 x N hexagonal lattice with cylindrical boundary conditions also are presented.

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T. E. Wetzel

Monte Carlo simulations on the effect of substrate geometry on adsorption and compression

Generalization of Kelvin's equation for compressible liquids in nanoconfinement

Adsorption Behavior of Repulsive Molecules

Monte Carlo simulations of phase transitions and adsorption isotherm discontinuities on surface compression

Configurational probabilities for monomers, dimers and trimers in fluids

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