Experimental estimation of the surface roughness distribution parameters in nanochannels

Experimental estimation of the surface roughness distribution parameters in nanochannels

A statistical model of surface roughness is developed to calculate the molecular flows in nanosystems. In this model, surface asperities are represented by a set of flat microareas connected by edges with each other and having normals that differ from the normal to the mean level. A Solver PRO-M ato...

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Bibliographic Details
Published in:Technical physics Vol. 56; no. 12; pp. 1802 - 1806
Main Authors: Memnonov, V. P., Ul’yanov, P. G.
Format: Journal Article
Language:English
Published: Dordrecht SP MAIK Nauka/Interperiodica 01-12-2011
Springer
Subjects:
Analysis
Classical and Continuum Physics
Electron and Ion Emission
Hard disks
Monte Carlo method
Physics
Physics and Astronomy
Surface
Toy industry
Roughness Parameter
Asperity Height
Direct Simula Tion Monte Carlo
Atomic Force Microscopy
Hard Disk
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Summary:A statistical model of surface roughness is developed to calculate the molecular flows in nanosystems. In this model, surface asperities are represented by a set of flat microareas connected by edges with each other and having normals that differ from the normal to the mean level. A Solver PRO-M atomic force microscope is used to measure the following two parameters of the microscopic roughness of a hard disk: the slope along a scan line and the asperity height. A large experimental sample from the measured values of these parameters is used to obtain a distribution function density for the angle of inclination and conditional distributions (with parameters dependent on this angle) for the asperity height and the area of the triangle formed by the height and the sides of the angle. The latter conditional exponential distribution turns out to be more convenient for calculating random quantities. The results can be employed to simulate boundary conditions when calculating molecular flows by statistical Monte Carlo methods and to estimate the properties of new materials for protective surface coatings in the nanosystems containing gas flows.
ISSN:1063-7842
1090-6525
DOI:10.1134/S1063784211120127