Microbial dispersal in unsaturated porous media: Characteristics of motile bacterial cell motions in unsaturated angular pore networks
Authored by Ali N Ebrahimi, Dani Or
Date Published: 2014
DOI: 10.1002/2014wr015897
Sponsors:
Swiss National Science Foundation (SNSF)
European Research Council (ERC)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
The dispersal rates of self-propelled microorganisms affect their
spatial interactions and the ecological functioning of microbial
communities. Microbial dispersal rates affect risk of contamination of
water resources by soil-borne pathogens, the inoculation of plant roots, or the rates of spoilage of food products. In contrast with the wealth
of information on microbial dispersal in water replete systems, very
little is known about their dispersal rates in unsaturated porous media.
The fragmented aqueous phase occupying complex soil pore spaces suppress
motility and limits dispersal ranges in unsaturated soil. The primary
objective of this study was to systematically evaluate key factors that
shape microbial dispersal in model unsaturated porous media to quantify
effects of saturation, pore space geometry, and chemotaxis on
characteristics of principles that govern motile microbial dispersion in
unsaturated soil. We constructed a novel 3-D angular pore network model
(PNM) to mimic aqueous pathways in soil for different hydration
conditions; within the PNM, we employed an individual-based model that
considers physiological and biophysical properties of motile and
chemotactic bacteria. The effects of hydration conditions on first
passage times in different pore networks were studied showing that
fragmentation of aquatic habitats under dry conditions sharply
suppresses nutrient transport and microbial dispersal rates in good
agreement with limited experimental data. Chemotactically biased mean
travel speed of microbial cells across 9 mm saturated PNM was
approximate to 3 mm/h decreasing exponentially to 0.45 mm/h for the PNM
at matric potential of -15kPa (for -35kPa, dispersal practically ceases
and the mean travel time to traverse the 9 mm PNM exceeds 1 year).
Results indicate that chemotaxis enhances dispersal rates by orders of
magnitude relative to random (diffusive) motions. Model predictions
considering microbial cell sizes relative to available liquid pathways
sizes were in good agreement with experimental results for unsaturated
soils. The new modeling platform enables quantitative consideration of
key biophysical factors (e.g., pore space heterogeneities and hydration
conditions) governing microbial interactions in 3-D soil pore spaces.
Tags
Escherichia-coli
Pollutant-degrading bacteria
Heterogeneous
populations
Capillary condensation
Hydraulic conductivity
Quantitative-analysis
Percolation theory
Dynamic properties
Wetting
liquid
Rough surfaces