Inverse estimation of parameters for multidomain flow models in soil columns with different macropore densities

Arora, Bhavna; Mohanty, Binayak P.; McGuire, Jennifer T.

doi:10.1029/2010wr009451

Cited by 76 publications

(90 citation statements)

References 71 publications

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“…7). Arora et al (2011) and Köhne and Mohanty (2005) did not consider the influence of coatings on the permeability, nor was this done in this study. It may be seen from Table 2 that the magnitude of the product α w K sa is similar for all studies, even though some of the other values (notably the ratios K sa /K sm and the values of α w ) differ by several orders of magnitude.…”

Section: Coupling Term In the Dual-permeability Modelmentioning

confidence: 99%

“…Köhne and Mohanty (2005) conceptualise the dual domain as a hollow cylindrical matrix that is filled with coarse sand in the middle to mimic the macropore domain. Arora et al (2011) based their parameters on a high density of macropore columns, and they calculated K a by averaging the hydraulic conductivities of the two pore domains (as adopted in this paper; see Eq. 7).…”

Section: Coupling Term In the Dual-permeability Modelmentioning

confidence: 99%

“…where α w (L −2 ) is the effective water transfer coefficient, and the relative hydraulic conductivity K a (L T −1 ) is calculated by averaging the hydraulic conductivities of the two pore domains (Arora et al, 2011;Laine-Kaulio et al, 2014):…”

Section: Subsurface Flow Modelmentioning

confidence: 99%

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Quantification of the influence of preferential flow on slope stability using a numerical modelling approach

Shao

Bogaard

Bakker

et al. 2015

Hydrol. Earth Syst. Sci.

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Abstract. The effect of preferential flow on the stability of landslides is studied through numerical simulation of two types of rainfall events on a hypothetical hillslope. A model is developed that consists of two parts. The first part is a model for combined saturated/unsaturated subsurface flow and is used to compute the spatial and temporal water pressure response to rainfall. Preferential flow is simulated with a dual-permeability continuum model consisting of a matrix domain coupled to a preferential flow domain. The second part is a soil mechanics model and is used to compute the spatial and temporal distribution of the local factor of safety based on the water pressure distribution computed with the subsurface flow model. Two types of rainfall events were considered: long-duration, low-intensity rainfall, and shortduration, high-intensity rainfall. The effect of preferential flow on slope stability is assessed through comparison of the failure area when subsurface flow is simulated with the dualpermeability model as compared to a single-permeability model (no preferential flow). For the low-intensity rainfall case, preferential flow has a positive effect on drainage of the hillslope resulting in a smaller failure area. For the highintensity rainfall case, preferential flow has a negative effect on the slope stability as the majority of rainfall infiltrates into the preferential flow domain when rainfall intensity exceeds the infiltration capacity of the matrix domain, resulting in larger water pressure and a larger failure area.

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Section: Coupling Term In the Dual-permeability Modelmentioning

confidence: 99%

Section: Coupling Term In the Dual-permeability Modelmentioning

confidence: 99%

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Quantification of the influence of preferential flow on slope stability using a numerical modelling approach

Shao

Bogaard

Bakker

et al. 2015

Hydrol. Earth Syst. Sci.

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show abstract

“…The study of preferential flow and transport through artificial macropores provides an opportunity to overcome many modeling challenges in natural soils because the macropore geometry and hydraulic properties can be well defined and controlled in a repeatable manner (Arora et al, 2011(Arora et al, , 2012Castiglione et al, 2003;Guzman et al, 2009;Pivetz and Steenhuis, 1995). Artificial macropores can be systematically created by leaving small cylindrical openings in repacked columns (Castiglione et al, 2003;Pivetz and Steenhuis, 1995) or by packing different sized sands to generate layers and/or lens with contrasting hydraulic conductivities (Bradford et al, 2004;Fontes et al, 1991;Morley et al, 1998;Saiers et al, 1994;Wang et al, 2013Wang et al, , 2014.…”

Section: Introductionmentioning

confidence: 99%

Estimation and upscaling of dual-permeability model parameters for the transport of E. coli D21g in soils with preferential flow

Wang

Bradford

Šimůnek

2014

Journal of Contaminant Hydrology

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Dual-permeability models are increasingly used to quantify the transport of solutes and microorganisms in soils with preferential flow. An ability to accurately determine the model parameters and their variation with preferential pathway characteristics is crucial for predicting the transport of microorganisms in the field. The dual-permeability model with optimized parameters was able to accurately describe the transport of E. coli D21g in columns with artificial macropores of different configurations and lengths at two ionic strength levels (1 and 20 mM NaCl). Correlations between the model parameters and the structural geometry of the preferential flow path were subsequently investigated. Decreasing the macropore length produced a decrease in the apparent saturated hydraulic conductivity of the macropore domain and an increase in the mass transfer between the macropore and matrix domains. The mass transfer coefficient was also found to be dependent on the configuration of the preferential flow pathway. A linear superposition approach was used to estimate field-scale preferential transport behavior for hypothetical fields with different amounts and configurations of macropores. Upscaling procedures were numerically investigated to predict this field-scale transport behavior from column-scale parameters. The upscaling method provided a satisfactory prediction of the field results under the tested scenarios. This information will be useful in assessing the risks of microbial transport due to preferential flow.

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“…Some of the commonly used continuum-scale models include (1) equivalent continuum model (ECM) [41]; (2) dual permeability model (DPM), dual or multiporosity model [42,43], multiple interacting continua approach (MINC) [44], and (3) discrete fracture and matrix model [45]. Among these three commonly used approaches, the dual-continuum approach has been extensively applied in different subsurface environments [46][47][48]. Broadly speaking, the dual-continuum approach considers two interacting regions, one associated with the less permeable intraaggregate pore region, or the soil matrix domain, and the other associated with the inter-aggregate pore region, or the fracture domain.…”

Section: Multicontinuum Representationsmentioning

confidence: 99%

Reactive transport codes for subsurface environmental simulation

et al. 2014

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A general description of the mathematical and numerical formulations used in modern numerical reactive transport codes relevant for subsurface environmental simulations is presented. The formulations are followed by short descriptions of commonly used and available subsurface simulators that consider continuum representations of flow, transport, and reactions in porous media. These formulations are applicable to most of the subsurface environmental benchmark problems included in this special issue. The list of codes described briefly here includes PHREEQC, HPx, PHT3D, OpenGeoSys (OGS), HYTEC, ORCHESTRA, TOUGHREACT, eSTOMP, HYDROGEOCHEM, CrunchFlow, MIN3P, and PFLOTRAN. The descriptions include a C. I. Steefel ( ) · B. Arora · S. Molins · N. Spycher

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Inverse estimation of parameters for multidomain flow models in soil columns with different macropore densities

Cited by 76 publications

References 71 publications

Quantification of the influence of preferential flow on slope stability using a numerical modelling approach

Quantification of the influence of preferential flow on slope stability using a numerical modelling approach

Estimation and upscaling of dual-permeability model parameters for the transport of E. coli D21g in soils with preferential flow

Reactive transport codes for subsurface environmental simulation

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