3–4D soil model as challenge for future soil research: Quantitative soil modeling based on the solid phase

Gerke, Horst H.; Vogel, Hans‐Jörg; Weber, Tobias; Meij, Marijn van der; Scholten, Thomas

doi:10.1002/jpln.202200239

Cited by 5 publications

(6 citation statements)

References 274 publications

(391 reference statements)

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“…Our results underline the capability of our model to investigate the opposing factors, which determine the nonlinear distribution of CO 2 in the soil profile. This emphasizes the need for micro–macro models exchanging information on different scales to investigate and quantify the effects of structural changes, variations in environmental conditions, or differences in the degradation processes in the hot spots of soils on carbon turnover (Baveye et al., 2018; Gerke et al., 2022; Pot et al., 2022b; Vereecken et al., 2016). This explicit spatially and temporally dynamic model contributes to understanding the linkage between soil architecture and functions from the micron to the pedon scale.…”

Section: Discussionmentioning

confidence: 99%

“…The prediction of the fate of carbon in soils or the impact of changes in the environmental conditions requires a fundamental understanding of the underlying processes at different scales. This necessitates the implementation of novel modeling approaches and, together with advanced experimental techniques down to the nanoscale, allows to challenge coherent hypotheses (Baveye et al, 2018;Gerke et al, 2022;Roose et al, 2016;Totsche et al, 2018;Vereecken et al, 2016). Several recent reviews point out the importance of incorporating process mechanisms at the pore scale in models to better understand carbon turnover in soils (Baveye et al, 2018;Meurer et al, 2020;Pot et al, 2022aPot et al, , 2022bVereecken et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Since the underlying processes are complex, this leads to nonlocal (in space and time) interrelations, which are poorly represented by constant parameters. In contrast to merely heuristic or lumped parameter models, a modeling approach with predictive capability requires that soil structure dynamics is taken into account in a temporally and spatially explicit way (Gerke et al., 2022; Pot et al., 2022b; Stockmann et al., 2013). Only then the influence of, for example, the physical protection of organic matter (OM) on its turnover can be evaluated in detail.…”

Section: Introductionmentioning

confidence: 99%

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Coupling scales in process‐based soil organic carbon modeling including dynamic aggregation

Zech,

Prechtel,

Ray

2024

J. Plant Nutr. Soil Sci.

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BackgroundCarbon storage and turnover in soils depend on the interplay of soil architecture, microbial activities, and soil organic matter (SOM) dynamics. For a fundamental understanding of the mechanisms that drive these processes, not only the exploitation of advanced experimental techniques down to the nanoscale is necessary but also spatially explicit and dynamic image‐based modeling at the pore scale.AimWe present a modeling approach that is capable of transferring microscale information into macroscale simulations at the profile scale. This enables the prediction of future developments of carbon fluxes and the impact of changes in the environmental conditions linking scales.MethodWe consider a mathematical model for CO2 transport across soil profiles (macroscale), which is informed by a pore‐scale (microscale) model for C turnover. It allows for the dynamic, self‐organized re‐arrangement of solid building units, aggregates and particulate organic matter (POM) based on surface interactions, realized by a cellular automaton method, and explicitly takes spatial effects on POM turnover such as occlusion into account. We further include the macroscopic environmental conditions water saturation, POM content, and oxygen concentration.ResultsThe coupled simulations of macroscopic transport and pore‐scale carbon and aggregate turnover reveal the complex, nonlinear interplay of the underlying processes. Limitations by diffusive transport, oxygen availability, texture‐dependent occlusion and turnover of OM drive CO2 production and carbon storage.ConclusionsThis emphasizes the need for such micro–macro models exchanging information on different scales to investigate and quantify the effects of structural changes, variations in environmental conditions, or degradation processes on carbon turnover.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Coupling scales in process‐based soil organic carbon modeling including dynamic aggregation

Zech,

Prechtel,

Ray

2024

J. Plant Nutr. Soil Sci.

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“…The impact of contrasting soil water contents on nutrient cycling is reviewed in this issue by Bauke et al (2022) who conclude that it needs to be studied from the molecular to the landscape scale. As a future perspective for soil system modeling, Gerke et al (2022) present within this issue a holistic approach to predict spatially distributed soil functions and their changes in response to external forcing. The authors cast the vision of a 3-4D soil model based on the solid phase, with time as the fourth dimension.…”

Section: Editorialmentioning

confidence: 99%

“…As a future perspective for soil system modeling, Gerke et al. (2022) present within this issue a holistic approach to predict spatially distributed soil functions and their changes in response to external forcing. The authors cast the vision of a 3–4D soil model based on the solid phase, with time as the fourth dimension.…”

Section: Editorialmentioning

confidence: 99%

Soil science challenges—An interdisciplinary overview of current and future topics

Pohl

Maurischat

Schiedung

et al. 2022

J. Plant Nutr. Soil Sci.

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This editorial was written by early career scientists in soil science and gives an overview of the articles published in the special issue “Soil Science Challenges—An Interdisciplinary Overview of Current and Future Topics” on the occasion of the 100th anniversary of Journal of Plant Nutrition and Soil Science. A broad range of articles addressing soil carbon dynamics from the microscale to landscape scale, multi‐dimensional modeling, improved land management practices, nutrient cycles, soil hydrology, plastic in soils, and interdisciplinarity of soil science is covered in this issue.

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Coupled hydro‐mechanical pore‐scale modeling of biopore‐coated clods for upscaling soil shrinkage and hydraulic properties

Barbosa,

Gerke

2024

Vadose Zone Journal

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Earthworms and plant roots are vital for macropore formation and stabilization. The organo‐mineral coating of biopore surfaces also regulates macropore‐matrix mass exchange during preferential flow. The influence of finer‐textured burrow coatings on macroscopic soil properties during shrinkage could potentially be assessed by upscaling pore‐scale hydraulic and mechanical simulations. The aim was to investigate the influence of micro parameters (particle size, stiffness, and bond strength) on macro parameters (i.e., shrinkage curve and soil hydraulic properties). Drainage experiments and simulations were carried out using biopore‐coated clod‐size samples compared to those without coating. Simulations were performed using a two‐phase pore‐scale finite volume coupled with discrete element model (DEM‐2PFV). The structural dynamics was characterized by analyzing the pore volume and soil shrinkage curve obtained from numerically determined data. The soil hydraulic parameters were described using uni‐ and bimodal van Genuchten (vG) functions. The drainage simulations revealed hydro‐mechanical dynamics characterized by Braudeau‐shrinkage curve subdomains: The matrix‐only samples, with lower particle bond strength, exhibited relatively higher shrinkage. The coated samples, with higher particle stiffness and bond strength, displayed greater hydro‐mechanical stability. The numerically determined initial value of the saturated hydraulic conductivity (Ks) was about 70 times larger for matrix‐only samples than for coated samples. As expected, for the nonrigid soil structures, constant Ks, α, and n values for bimodal vG model resulted in prediction errors. Upscaling DEM‐2PFV pore‐scale model outcomes quantifies micro‐coating effects on macro hydro‐mechanics. This yields void ratio‐based soil water retention and hydraulic conductivity functions, advancing macroscopic soil hydraulic models and enhancing structured soil flow and transport descriptions.

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3–4D soil model as challenge for future soil research: Quantitative soil modeling based on the solid phase

Cited by 5 publications

References 274 publications

Coupling scales in process‐based soil organic carbon modeling including dynamic aggregation

Coupling scales in process‐based soil organic carbon modeling including dynamic aggregation

Soil science challenges—An interdisciplinary overview of current and future topics

Coupled hydro‐mechanical pore‐scale modeling of biopore‐coated clods for upscaling soil shrinkage and hydraulic properties

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