Behavior of confined fluids in nanoslit pores: the normal pressure tensor

The aim of our research is to develop a theory, which can predict the behavior of confined fluids in nanoslit pores. The nanoslit pores studied in this work consist of two structureless and parallel walls in the xy plane located at z  = 0 and z  =  H , in equilibrium with a bulk homogeneous fluid at...

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Published inMicrofluidics and nanofluidics Vol. 8; no. 1; pp. 97 - 104
Main Authors (Ezzat) Keshavarzi, Tahmineh, Sedaghat, Farideh, Mansoori, G. Ali
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer-Verlag 2010
Springer
Springer Nature B.V
Subjects
Analytical Chemistry
Applied fluid mechanics
Biomedical Engineering and Bioengineering
Engineering
Engineering Fluid Dynamics
Exact sciences and technology
Fluid dynamics
Fluidics
Fundamental areas of phenomenology (including applications)
Nanotechnology and Microengineering
Physics
Pores
Potential energy
Research Paper
Studies
Stress tensor
Hard-sphere fluid
Normal pressure tensor
Behavior of nano-confined fluid
Nanoconfined fluid
Nanoslit pore
Fluid wall interaction
Pore
Theoretical study
Nanofluidics
Nanostructures
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Summary:The aim of our research is to develop a theory, which can predict the behavior of confined fluids in nanoslit pores. The nanoslit pores studied in this work consist of two structureless and parallel walls in the xy plane located at z  = 0 and z  =  H , in equilibrium with a bulk homogeneous fluid at the same temperature and at a given uniform bulk density. We have derived the following general equation for prediction of the normal pressure tensor P zz of confined inhomogeneous fluids in nanoslit pores: where is the intermolecular position vector of molecule 2 with respect to molecule 1 and is the projection of distance of molecule 1 from molecule 2 in the z -direction. This equation may be solved for any fluid possessing a defined intermolecular pair-potential energy function, confined in a nanoslit pore and with a given fluid molecules—wall interaction potential function ϕ ext . As an important example of its application we have solved this equation for the hard-sphere fluid confined between two parallel–structureless hard walls with different nanometer distances and at various uniform bulk densities. Our results indicate the oscillatory form of the normal pressure tensor versus distance from the wall at high densities. As the density of the nanoconfined fluid decreases, the height and depth of the normal pressure tensor oscillations are reduced.
ISSN:1613-4982
1613-4990
DOI:10.1007/s10404-009-0449-y