Numerical study of multilayer adsorption on fractal surfaces

A. W. Adamson; A.V. Neimark; B. Sahouli; B. Sahouli; B. Sahouli; B.B. Mandelbrot; D. Avnir; H. Darmstadt; Hao Qi; I.M.K. Ismail; J. Ma; Jian Ma; M. Jaroniec; M. Kardar; M. Kardar; O. Biham; P. G. de Gennes; P. Pfeifer; P. Pfeifer; P. Pfeifer; P.-z. Wong; Po-zen Wong; R.M. Barrer; S. Blacher; S. J. Gregg; S.M. Cohen; Y. Yin

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Numerical study of multilayer adsorption on fractal surfaces

Authors: A. W. Adamson
A.V. Neimark
B. Sahouli
B. Sahouli
B. Sahouli
B.B. Mandelbrot
D. Avnir
H. Darmstadt
Hao Qi
I.M.K. Ismail
J. Ma
Jian Ma
M. Jaroniec
M. Kardar
M. Kardar
O. Biham
P. G. de Gennes
P. Pfeifer
P. Pfeifer
P. Pfeifer
P.-z. Wong
Po-zen Wong
R.M. Barrer
S. Blacher
S. J. Gregg
S.M. Cohen
Y. Yin
Publication date: 7 October 2000
Publisher: 'American Physical Society (APS)'
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Abstract

We report a numerical study of van der Waals adsoprtion and capillary condensation effects on self-similar fractal surfaces. An assembly of uncoupled spherical pores with a power-law distributin of radii is used to model fractal surfaces with adjustable dimensions. We find that the commonly used fractal Frankel-Halsey-Hill equation systematically fails to give the correct dimension due to crossover effects, consistent with the findings of recent experiments. The effects of pore coupling and curvature dependent surface tension were also studied.Comment: 11 pages, 3 figure

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