Here, is the volumetric flowrate in , is the pressure difference in Pa, is the pore diameter in m, and is the fluid's dynamic viscosity in Pa·s. The flow can also be expressed as a molecular flux as:
Here, is the molecular flux in atoms/m2·sec, is the average of the pressures on either side of the orifice, is the Boltzmann constant, ( J/K), and is the absolute temperature in K.
Sampson flow is the macroscopic analog of effusion flow, which describes stochastic diffusion of molecules through an orifice much smaller than the mean-free-path of the gas molecules. For pore diameters on the order of the mean-free-path of the fluid, flow will occur with contributions from the molecular regime as well as the viscous regime, obeying the dusty gas model according to the following equation:[6]
Here, is the total volumetric flowrate and is the volumetric flowrate according to the law of effusion. As it turns out, for many gasses, we notice equal contributions from molecular and viscous regimes when the pore size is significantly larger than the mean-free-path of the fluid, for nitrogen this occurs at a pore diameter of 393 nm, 6.0× larger than the mean-free-path.[citation needed]
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^Jensen, K. H.; Valente, A. X. C. N.; Stone, H. A. (2014). "Flow rate through microfilters: Influence of the pore size distribution, hydrodynamic interactions, wall slip, and inertia". Physics of Fluids. 26 (5): 052004. Bibcode:2014PhFl...26e2004J. doi:10.1063/1.4876937.
^Roscoe, R. (1949). "XXXI. The flow of viscous fluids round plane obstacles". The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science. 40 (302): 338–351. doi:10.1080/14786444908561255.