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Anisotropic molecular diffusion in confinement I: Transport of small particles in potential and density gradients

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arxiv 2212.09545 v2 pith:LQ7A5O5S submitted 2022-12-19 cond-mat.soft cond-mat.mtrl-scicond-mat.stat-mechphysics.chem-phphysics.comp-ph

Anisotropic molecular diffusion in confinement I: Transport of small particles in potential and density gradients

classification cond-mat.soft cond-mat.mtrl-scicond-mat.stat-mechphysics.chem-phphysics.comp-ph
keywords diffusioninterfaceslocalspatiallyanisotropiccoefficientsdensitydependent
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Hypothesis: Diffusion in confinement is an important fundamental problem with significant implications for applications of supported liquid phases. However, resolving the spatially dependent diffusion coefficient, parallel and perpendicular to interfaces, has been a standing issue. In the vicinity of interfaces, density fluctuations as a consequence of layering locally impose statistical drift, which impedes the analysis of spatially dependent diffusion coefficients even further. We hypothesise, that we can derive a model to spatially resolve interface-perpendicular diffusion coefficients based on local lifetime statistics with an extension to explicitly account for the effect of local drift using the Smoluchowski equation, that allows us to resolve anisotropic and spatially dependent diffusivity landscapes at interfaces. Methods and simulations: An analytic relation between local crossing times in system slices and diffusivity as well as an explicit term for calculating drift-induced systematic errors is presented. The method is validated on Molecular Dynamics simulations of bulk water and applied to simulations of water in slit pores. Findings: After validation on bulk liquids, we clearly demonstrate the anisotropic nature of diffusion coefficients at interfaces. Significant spatial variations in the diffusivities correlate with interface-induced structuring but cannot be solely attributed to the drift induced by local density fluctuations.

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