Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis

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Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis. / Han, Eusun; Kirkegaard, John A.; White, Rosemary; Smith, Abraham George; Thorup-Kristensen, Kristian; Kautz, Timo; Athmann, Miriam.

I: Geoderma, Bind 425, 116072, 2022.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Han, E, Kirkegaard, JA, White, R, Smith, AG, Thorup-Kristensen, K, Kautz, T & Athmann, M 2022, 'Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis', Geoderma, bind 425, 116072. https://doi.org/10.1016/j.geoderma.2022.116072

APA

Han, E., Kirkegaard, J. A., White, R., Smith, A. G., Thorup-Kristensen, K., Kautz, T., & Athmann, M. (2022). Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis. Geoderma, 425, [116072]. https://doi.org/10.1016/j.geoderma.2022.116072

Vancouver

Han E, Kirkegaard JA, White R, Smith AG, Thorup-Kristensen K, Kautz T o.a. Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis. Geoderma. 2022;425. 116072. https://doi.org/10.1016/j.geoderma.2022.116072

Author

Han, Eusun ; Kirkegaard, John A. ; White, Rosemary ; Smith, Abraham George ; Thorup-Kristensen, Kristian ; Kautz, Timo ; Athmann, Miriam. / Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis. I: Geoderma. 2022 ; Bind 425.

Bibtex

@article{9494d98fa4d040a48a2e6f64006b9713,
title = "Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis",
abstract = "Soil biopore genesis is a dynamic and context-dependent process. Yet integrative investigations of biopore genesis under varying soil type, tillage and vegetation history are rare. Recent advances in Machine Learning (ML) made faster and more accurate image analysis possible. We validated a model trained on Convolutional Neural Network (CNN) using a multisite dataset from varying soil types (Luvisol, Cambisol and Kandosol), tillage (deep ploughing and without deep ploughing) and vegetation history (taprooted and fibrous-rooted crops) to automatically predict biopore formation. The model trained on the multisite dataset outperformed individually trained single-site models, especially when the dataset contained images with noise and/or fewer biopores. Our model successfully replicated previously established treatment effects but provided new insights at more detailed scales and for different pore-size classes. These insights demonstrated that effects of deep ploughing on soil biopores can persist for more than 50 years and are more pronounced on the Luvisol rather than the Cambisol soil type. The effects of perennial fodder crops with high biopore generating capacity were also shown to persist for at least a decade. re-growing the same fodder crops or a mixture with grass had no further impact on biopore density but generated a shift in pore-size classes from large to smaller biopores. We suspect this is likely to have resulted from three possible scenarios; (1) newly created fine pores (1–4 mm); (2) blockage of large-sized pores by earthworm faeces; (3) decrease in pore diameter. In summary, by using a single robust model trained on the multisite dataset, we were able to generate new insights on pore-size distribution as affected by site, vegetation, and deep ploughing. We have demonstrated that Deep Learning-based image analysis can provide easier biopore quantification and can generate models that provide novel insights across different research settings consistently and accurately.",
keywords = "AI, Convolutional neural network, Deep tillage, Perennial crops, RootPainter, Subsoil",
author = "Eusun Han and Kirkegaard, {John A.} and Rosemary White and Smith, {Abraham George} and Kristian Thorup-Kristensen and Timo Kautz and Miriam Athmann",
note = "Publisher Copyright: {\textcopyright} 2022 The Authors",
year = "2022",
doi = "10.1016/j.geoderma.2022.116072",
language = "English",
volume = "425",
journal = "Geoderma",
issn = "0016-7061",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Deep learning with multisite data reveals the lasting effects of soil type, tillage and vegetation history on biopore genesis

AU - Han, Eusun

AU - Kirkegaard, John A.

AU - White, Rosemary

AU - Smith, Abraham George

AU - Thorup-Kristensen, Kristian

AU - Kautz, Timo

AU - Athmann, Miriam

N1 - Publisher Copyright: © 2022 The Authors

PY - 2022

Y1 - 2022

N2 - Soil biopore genesis is a dynamic and context-dependent process. Yet integrative investigations of biopore genesis under varying soil type, tillage and vegetation history are rare. Recent advances in Machine Learning (ML) made faster and more accurate image analysis possible. We validated a model trained on Convolutional Neural Network (CNN) using a multisite dataset from varying soil types (Luvisol, Cambisol and Kandosol), tillage (deep ploughing and without deep ploughing) and vegetation history (taprooted and fibrous-rooted crops) to automatically predict biopore formation. The model trained on the multisite dataset outperformed individually trained single-site models, especially when the dataset contained images with noise and/or fewer biopores. Our model successfully replicated previously established treatment effects but provided new insights at more detailed scales and for different pore-size classes. These insights demonstrated that effects of deep ploughing on soil biopores can persist for more than 50 years and are more pronounced on the Luvisol rather than the Cambisol soil type. The effects of perennial fodder crops with high biopore generating capacity were also shown to persist for at least a decade. re-growing the same fodder crops or a mixture with grass had no further impact on biopore density but generated a shift in pore-size classes from large to smaller biopores. We suspect this is likely to have resulted from three possible scenarios; (1) newly created fine pores (1–4 mm); (2) blockage of large-sized pores by earthworm faeces; (3) decrease in pore diameter. In summary, by using a single robust model trained on the multisite dataset, we were able to generate new insights on pore-size distribution as affected by site, vegetation, and deep ploughing. We have demonstrated that Deep Learning-based image analysis can provide easier biopore quantification and can generate models that provide novel insights across different research settings consistently and accurately.

AB - Soil biopore genesis is a dynamic and context-dependent process. Yet integrative investigations of biopore genesis under varying soil type, tillage and vegetation history are rare. Recent advances in Machine Learning (ML) made faster and more accurate image analysis possible. We validated a model trained on Convolutional Neural Network (CNN) using a multisite dataset from varying soil types (Luvisol, Cambisol and Kandosol), tillage (deep ploughing and without deep ploughing) and vegetation history (taprooted and fibrous-rooted crops) to automatically predict biopore formation. The model trained on the multisite dataset outperformed individually trained single-site models, especially when the dataset contained images with noise and/or fewer biopores. Our model successfully replicated previously established treatment effects but provided new insights at more detailed scales and for different pore-size classes. These insights demonstrated that effects of deep ploughing on soil biopores can persist for more than 50 years and are more pronounced on the Luvisol rather than the Cambisol soil type. The effects of perennial fodder crops with high biopore generating capacity were also shown to persist for at least a decade. re-growing the same fodder crops or a mixture with grass had no further impact on biopore density but generated a shift in pore-size classes from large to smaller biopores. We suspect this is likely to have resulted from three possible scenarios; (1) newly created fine pores (1–4 mm); (2) blockage of large-sized pores by earthworm faeces; (3) decrease in pore diameter. In summary, by using a single robust model trained on the multisite dataset, we were able to generate new insights on pore-size distribution as affected by site, vegetation, and deep ploughing. We have demonstrated that Deep Learning-based image analysis can provide easier biopore quantification and can generate models that provide novel insights across different research settings consistently and accurately.

KW - AI

KW - Convolutional neural network

KW - Deep tillage

KW - Perennial crops

KW - RootPainter

KW - Subsoil

U2 - 10.1016/j.geoderma.2022.116072

DO - 10.1016/j.geoderma.2022.116072

M3 - Journal article

AN - SCOPUS:85135954790

VL - 425

JO - Geoderma

JF - Geoderma

SN - 0016-7061

M1 - 116072

ER -

ID: 318034117