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Autori principali: Norouzi, Sarem, Moldrup, Per, Moseley, Ben, Robinson, David, Or, Dani, Hohenbrink, Tobias L., Minasny, Budiman, Sadeghi, Morteza, Arthur, Emmanuel, Tuller, Markus, Greve, Mogens H., de Jonge, Lis W.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.25554
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author Norouzi, Sarem
Moldrup, Per
Moseley, Ben
Robinson, David
Or, Dani
Hohenbrink, Tobias L.
Minasny, Budiman
Sadeghi, Morteza
Arthur, Emmanuel
Tuller, Markus
Greve, Mogens H.
de Jonge, Lis W.
author_facet Norouzi, Sarem
Moldrup, Per
Moseley, Ben
Robinson, David
Or, Dani
Hohenbrink, Tobias L.
Minasny, Budiman
Sadeghi, Morteza
Arthur, Emmanuel
Tuller, Markus
Greve, Mogens H.
de Jonge, Lis W.
contents Soil physics models have long relied on simplifying assumptions to represent complex processes, yet such assumptions can strongly bias model predictions. Here, we propose a paradigm-shifting differentiable hybrid modeling (DHM) framework that instead of simplifying the unknown, learns it from data. As a proof of concept, we apply the hybrid approach to the challenge of partitioning the soil water retention curve (SWRC) into capillary and adsorbed water components, a problem where traditional assumptions have led to divergent results. The hybrid framework derives this partitioning directly from data while remaining guided by a few parsimonious and universally accepted physical constraints. Using basic soil physical properties as inputs, the hybrid model couples an analytical formula for the dry end of the SWRC with data-driven physics-informed neural networks that learn the wet end, the transition between the two ends, and key soil-specific parameters. The model was trained on a SWRC dataset from 482 undisturbed soil samples from Central Europe, spanning a broad range of soil texture classes and organic carbon contents. The hybrid model successfully learned both the overall shape and the capillary and adsorbed components of the SWRC. Notably, the model revealed physically meaningful pore-scale features without relying on explicit geometrical assumptions about soil pore shape or its distribution. Moreover, the model revealed a distinctly nonlinear transition between capillary and adsorbed domains, challenging the linear assumptions invoked in previous studies. The methodology introduced here provides a blueprint for learning other soil processes where high-quality datasets are available but mechanistic understanding is incomplete.
format Preprint
id arxiv_https___arxiv_org_abs_2510_25554
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning Soil Physics from Partial Knowledge and Data: Partitioning Capillary and Adsorbed Soil Water
Norouzi, Sarem
Moldrup, Per
Moseley, Ben
Robinson, David
Or, Dani
Hohenbrink, Tobias L.
Minasny, Budiman
Sadeghi, Morteza
Arthur, Emmanuel
Tuller, Markus
Greve, Mogens H.
de Jonge, Lis W.
Geophysics
Soil physics models have long relied on simplifying assumptions to represent complex processes, yet such assumptions can strongly bias model predictions. Here, we propose a paradigm-shifting differentiable hybrid modeling (DHM) framework that instead of simplifying the unknown, learns it from data. As a proof of concept, we apply the hybrid approach to the challenge of partitioning the soil water retention curve (SWRC) into capillary and adsorbed water components, a problem where traditional assumptions have led to divergent results. The hybrid framework derives this partitioning directly from data while remaining guided by a few parsimonious and universally accepted physical constraints. Using basic soil physical properties as inputs, the hybrid model couples an analytical formula for the dry end of the SWRC with data-driven physics-informed neural networks that learn the wet end, the transition between the two ends, and key soil-specific parameters. The model was trained on a SWRC dataset from 482 undisturbed soil samples from Central Europe, spanning a broad range of soil texture classes and organic carbon contents. The hybrid model successfully learned both the overall shape and the capillary and adsorbed components of the SWRC. Notably, the model revealed physically meaningful pore-scale features without relying on explicit geometrical assumptions about soil pore shape or its distribution. Moreover, the model revealed a distinctly nonlinear transition between capillary and adsorbed domains, challenging the linear assumptions invoked in previous studies. The methodology introduced here provides a blueprint for learning other soil processes where high-quality datasets are available but mechanistic understanding is incomplete.
title Learning Soil Physics from Partial Knowledge and Data: Partitioning Capillary and Adsorbed Soil Water
topic Geophysics
url https://arxiv.org/abs/2510.25554