Aaron A. Mohammed
2021
Dual‐permeability modeling of preferential flow and snowmelt partitioning in frozen soils
Aaron A. Mohammed,
Edwin E. Cey,
Masaki Hayashi,
Michael V. Callaghan,
Youngjin Park,
Killian Miller,
Steven K. Frey
Vadose Zone Journal, Volume 20, Issue 2
The infiltrability of frozen soils modulates the partitioning of snowmelt between infiltration and runoff in cold regions. Preferential flow in macropores may enhance infiltration, but flow dynamics in frozen soil are complicated by soil heat transfer processes. We developed a dual-permeability model that considers the interacting effects of freeze–thaw and preferential flow on infiltration and runoff generation in structured soils. This formulation was incorporated into the fully integrated groundwater–surface water model HydroGeoSphere, to represent water–ice phase change in macropores such that porewater freezing is governed by macropore–matrix heat exchange. Model performance was evaluated against laboratory experiments and synthetic test cases designed to examine the effects of preferential flow on snowmelt partitioning between infiltration, runoff, and drainage. Simulations were able to reproduce experimental observations of rapid infiltration and drainage behavior due to macropores very well, and approximated soil thaw to an acceptable degree. Simulation of measured data highlighted the importance of macropore hydraulic conductivity, as well as macropore–matrix heat and water transfer, on controlling preferential flow dynamics. Test cases replicated a range of snowmelt partitioning behavior commonly observed in frozen soils, including subsurface conditions that produce rapid infiltration and deeper drainage, the contrast between limited vs. unlimited infiltration responses to snowmelt, and the temporal evolution of runoff generation. This study demonstrates the important influence that water freezing along preferential flowpaths can have on infiltrability and runoff characteristics in frozen soils and provides a physically based description of this mechanism that links infiltration behavior to hydraulic and thermal properties of structured soils.
2018
Snowmelt Infiltration and Macropore Flow in Frozen Soils: Overview, Knowledge Gaps, and a Conceptual Framework
Aaron A. Mohammed,
Barret L. Kurylyk,
Edwin E. Cey,
Masaki Hayashi
Vadose Zone Journal, Volume 17, Issue 1
Review highlights the hydrological importance of macropore flow in frozen soils. Governing flow mechanisms and infiltration and refreezing dynamics are discussed. Research is needed to integrate macropore flow and soil freeze–thaw theory. Dual‐domain models of macropore flow should be adapted to frozen ground. A conceptual framework for modeling frozen macroporous soils is proposed.
A Coupled Soil Water Balance Model for Simulating Depression‐Focused Groundwater Recharge
Saskia Noorduijn,
Masaki Hayashi,
Getachew Adem Mohammed,
Aaron A. Mohammed
Vadose Zone Journal, Volume 17, Issue 1
Ephemeral ponds in depressions are the foci of groundwater recharge in the Canadian Prairies. Freeze–thaw processes influence snowmelt runoff and depression‐focused recharge. A new water balance model was developed to represent these processes. The water balance model successfully simulated the observed soil processes. This model will provide a tool to estimate recharge in the prairie landscape.
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Co-authors
- Masaki Hayashi 3
- Edwin E. Cey 2
- Michael V. Callaghan 1
- Youngjin Park 1
- Killian Miller 1
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