Anomalous dispersion, renormalization groups, scaling laws and classification: A reflection on recent efforts

•Renormalization group techniques are used to upscale dispersive/diffusive processes.•Renormalization group techniques are used to classify dispersive/diffusive processes.•Random renormalization groups are used for processes without self-similarity.•Bayesian scaling laws are presented. Motivated by...

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Bibliographic Details
Published in:Advances in water resources 2013-12, Vol.62, p.207-214
Main Authors: Cushman, John H., O’Malley, Daniel, Park, Moongyu
Format: Article
Language:English
Subjects:
Anomalous diffusion/dispersion
Central limit theorems
Earth sciences
Earth, ocean, space
Exact sciences and technology
Hydrogeology
Hydrology. Hydrogeology
Renormalization groups
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Summary:•Renormalization group techniques are used to upscale dispersive/diffusive processes.•Renormalization group techniques are used to classify dispersive/diffusive processes.•Random renormalization groups are used for processes without self-similarity.•Bayesian scaling laws are presented. Motivated by the need to understand the dynamics of motile particles in porous media, our team has applied renormalization group techniques to both upscale and classify anomalous dispersive/diffusive behavior. Central limit theorems, which lead to a specific type of renormalization group, are employed in several cases to upscale transport of motile particles in porous media that display a specific type of fractal character. The old standby classification for diffusion (which we use interchangeably with dispersion) says a particle is anomalous if its mean square displacement is not linear in time. This physically intuitive concept, is shown to be inadequate, and so is replaced by a scheme that relies on the fixed points of specific renormalization group operators. Various asymptotic limits are examined, and scaling laws for the limits are derived. A random renormalization operator is introduced for processes with multiple asymptotes and unknown self-similarity index, and a Bayesian tool is employed to obtain scaling laws that are weighted averages of power laws.
ISSN:0309-1708
1872-9657
DOI:10.1016/j.advwatres.2013.07.001