Meurer , KatharinaBarron, JennieChenu, ClaireCoucheney, ElsaFielding, MatthewHallett, PaulHerrmann, AnkeKeller, ThomasKoestel, JohnLarsbo, MatsLewan, ElisabetOr, DaniParsons, DavidParvin , NargishTaylor, Astrid RVereecken, HarryJarvis, Nicholas2020-09-272020-09-272020-10Meurer , K, Barron, J, Chenu, C, Coucheney, E, Fielding, M, Hallett, P, Herrmann, A, Keller, T, Koestel, J, Larsbo, M, Lewan, E, Or, D, Parsons, D, Parvin , N, Taylor, A R, Vereecken, H & Jarvis, N 2020, 'A framework for modelling soil structure dynamics induced by biological activity', Global Change Biology, vol. 26, no. 10, pp. 5382-5403. https://doi.org/10.1111/gcb.152891354-1013ORCID: /0000-0001-7542-7832/work/162252045https://hdl.handle.net/2164/15174Acknowledgments: This work was funded by the Swedish Research Council for Sustainable Development (FORMAS) in the project “Soil structure and soil degradation: improved model tools to meet sustainable development goals under climate and land use change” (grant no. 2018-02319). We would also like to thank Mikael Sasha Dooha for carrying out the measurements for the water retention curves shown in figure 4.222858001engSDG 13 - Climate ActionSDG 15 - Life on Landbiological processesdegradationdynamicsmodellingsoilstructurePHYSICAL-PROPERTIESARBUSCULAR MYCORRHIZAL FUNGIWATER RETENTION CURVEHYDRAULIC-PROPERTIESORGANIC-MATTERBULK-DENSITYRAY COMPUTED-TOMOGRAPHYEARTHWORM BURROW SYSTEMSPORE STRUCTURE CHANGESENCHYTRAEIDAE OLIGOCHAETAQH301 BiologyGeneral Environmental ScienceGlobal and Planetary ChangeEcologyEnvironmental ChemistrySupplementary DataQH301Journal article10.1111/gcb.15289http://www.scopus.com/inward/record.url?scp=85089694128&partnerID=8YFLogxK2610