Bounded fractional diffusion in geological media: Definition and Lagrangian approximation

Yong Zhang; Christopher T. Green; Eric M. LaBolle; Roseanna M. Neupauer; Hong-Guang Sun

doi:10.1002/2016WR019178

Bounded fractional diffusion in geological media: Definition and Lagrangian approximation

Water Resources Research

By: Yong Zhang, Christopher T. Green, Eric M. LaBolle, Roseanna M. Neupauer, and Hong-Guang Sun

https://doi.org/10.1002/2016WR019178

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Abstract

Spatiotemporal Fractional-Derivative Models (FDMs) have been increasingly used to simulate non-Fickian diffusion, but methods have not been available to define boundary conditions for FDMs in bounded domains. This study defines boundary conditions and then develops a Lagrangian solver to approximate bounded, one-dimensional fractional diffusion. Both the zero-value and non-zero-value Dirichlet, Neumann, and mixed Robin boundary conditions are defined, where the sign of Riemann-Liouville fractional derivative (capturing non-zero-value spatial-nonlocal boundary conditions with directional super-diffusion) remains consistent with the sign of the fractional-diffusive flux term in the FDMs. New Lagrangian schemes are then proposed to track solute particles moving in bounded domains, where the solutions are checked against analytical or Eularian solutions available for simplified FDMs. Numerical experiments show that the particle-tracking algorithm for non-Fickian diffusion differs from Fickian diffusion in relocating the particle position around the reflective boundary, likely due to the non-local and non-symmetric fractional diffusion. For a non-zero-value Neumann or Robin boundary, a source cell with a reflective face can be applied to define the release rate of random-walking particles at the specified flux boundary. Mathematical definitions of physically meaningful nonlocal boundaries combined with bounded Lagrangian solvers in this study may provide the only viable techniques at present to quantify the impact of boundaries on anomalous diffusion, expanding the applicability of FDMs from infinite do mains to those with any size and boundary conditions.

Suggested Citation

Zhang, Y., Green, C.T., LaBolle, E.M., Neupauer, R.M., and Sun, H., 2016, Bounded fractional diffusion in geological media: Definition and Lagrangian approximation: Water Resources Research, v. 52, no. 11, p. 8561-8577, https://doi.org/10.1002/2016WR019178.

ISSN: 1944-7973 (online)

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Bounded fractional diffusion in geological media: Definition and Lagrangian approximation
Series title	Water Resources Research
DOI	10.1002/2016WR019178
Volume	52
Issue	11
Publication Date	November 12, 2016
Year Published	2016
Language	English
Publisher	American Geophysical Union
Publisher location	Washington, D.C.
Contributing office(s)	National Research Program - Western Branch, Toxic Substances Hydrology Program
Description	17 p.
First page	8561
Last page	8577