Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts

Nevo Sagi; Amir Sagy; Vincent J.M.N.L. Felde; Dror Hawlena

doi:10.1016/j.geoderma.2025.117193

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Originalsprache	Englisch
Aufsatznummer	117193
Fachzeitschrift	GEODERMA
Jahrgang	454
Frühes Online-Datum	31 Jan. 2025
Publikationsstatus	Veröffentlicht - Feb. 2025

Abstract

Biological soil crusts (biocrusts) play key roles in dryland ecosystem processes by mediating soil surface conditions. How consumption by macro-arthropods affects biocrust surface roughness and carbon cycling remains largely unknown. In two separate experiments, we addressed this knowledge gap by exposing biocrusts to varying levels of desert isopod crustivory (i.e. grazing intensity), and quantifying the consequences for microtopography, CO₂ efflux and carbon fixation. Biocrust surface roughness peaked under intermediate crustivory pressure, implying that varying levels of crustivory may have opposing consequences for ecosystem processes such as carbon cycling, water infiltration, runoff generation and soil erosion. However, crustivory had a monotonic negative effect on biocrust carbon cycling. Biocrust CO₂ efflux decreased with increasing crustivory, but recovered after several wetting events. Crustivory had a negative effect on biocrust C fixation, but only after the CO₂ efflux recovered to pre-crustivory levels. Our findings suggest that macro-crustivores may play a pivotal role in regulating biocrust functioning, introducing a whole new line of trophic research that may transform our understanding of ecosystems dynamics in drylands.

ASJC Scopus Sachgebiete

Agrar- und Biowissenschaften (insg.)
Bodenkunde

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Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts. / Sagi, Nevo; Sagy, Amir; Felde, Vincent J.M.N.L. et al.
in: GEODERMA, Jahrgang 454, 117193, 02.2025.

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

Sagi, N, Sagy, A, Felde, VJMNL & Hawlena, D 2025, 'Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts', GEODERMA, Jg. 454, 117193. https://doi.org/10.1016/j.geoderma.2025.117193

Sagi, N., Sagy, A., Felde, V. J. M. N. L., & Hawlena, D. (2025). Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts. GEODERMA, 454, Artikel 117193. https://doi.org/10.1016/j.geoderma.2025.117193

Sagi N, Sagy A, Felde VJMNL, Hawlena D. Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts. GEODERMA. 2025 Feb;454:117193. Epub 2025 Jan 31. doi: 10.1016/j.geoderma.2025.117193

Sagi, Nevo ; Sagy, Amir ; Felde, Vincent J.M.N.L. et al. / Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts. in: GEODERMA. 2025 ; Jahrgang 454.

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abstract = "Biological soil crusts (biocrusts) play key roles in dryland ecosystem processes by mediating soil surface conditions. How consumption by macro-arthropods affects biocrust surface roughness and carbon cycling remains largely unknown. In two separate experiments, we addressed this knowledge gap by exposing biocrusts to varying levels of desert isopod crustivory (i.e. grazing intensity), and quantifying the consequences for microtopography, CO2 efflux and carbon fixation. Biocrust surface roughness peaked under intermediate crustivory pressure, implying that varying levels of crustivory may have opposing consequences for ecosystem processes such as carbon cycling, water infiltration, runoff generation and soil erosion. However, crustivory had a monotonic negative effect on biocrust carbon cycling. Biocrust CO2 efflux decreased with increasing crustivory, but recovered after several wetting events. Crustivory had a negative effect on biocrust C fixation, but only after the CO2 efflux recovered to pre-crustivory levels. Our findings suggest that macro-crustivores may play a pivotal role in regulating biocrust functioning, introducing a whole new line of trophic research that may transform our understanding of ecosystems dynamics in drylands.",

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author = "Nevo Sagi and Amir Sagy and Felde, {Vincent J.M.N.L.} and Dror Hawlena",

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AU - Sagi, Nevo

AU - Sagy, Amir

AU - Felde, Vincent J.M.N.L.

AU - Hawlena, Dror

PY - 2025/2

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N2 - Biological soil crusts (biocrusts) play key roles in dryland ecosystem processes by mediating soil surface conditions. How consumption by macro-arthropods affects biocrust surface roughness and carbon cycling remains largely unknown. In two separate experiments, we addressed this knowledge gap by exposing biocrusts to varying levels of desert isopod crustivory (i.e. grazing intensity), and quantifying the consequences for microtopography, CO2 efflux and carbon fixation. Biocrust surface roughness peaked under intermediate crustivory pressure, implying that varying levels of crustivory may have opposing consequences for ecosystem processes such as carbon cycling, water infiltration, runoff generation and soil erosion. However, crustivory had a monotonic negative effect on biocrust carbon cycling. Biocrust CO2 efflux decreased with increasing crustivory, but recovered after several wetting events. Crustivory had a negative effect on biocrust C fixation, but only after the CO2 efflux recovered to pre-crustivory levels. Our findings suggest that macro-crustivores may play a pivotal role in regulating biocrust functioning, introducing a whole new line of trophic research that may transform our understanding of ecosystems dynamics in drylands.

AB - Biological soil crusts (biocrusts) play key roles in dryland ecosystem processes by mediating soil surface conditions. How consumption by macro-arthropods affects biocrust surface roughness and carbon cycling remains largely unknown. In two separate experiments, we addressed this knowledge gap by exposing biocrusts to varying levels of desert isopod crustivory (i.e. grazing intensity), and quantifying the consequences for microtopography, CO2 efflux and carbon fixation. Biocrust surface roughness peaked under intermediate crustivory pressure, implying that varying levels of crustivory may have opposing consequences for ecosystem processes such as carbon cycling, water infiltration, runoff generation and soil erosion. However, crustivory had a monotonic negative effect on biocrust carbon cycling. Biocrust CO2 efflux decreased with increasing crustivory, but recovered after several wetting events. Crustivory had a negative effect on biocrust C fixation, but only after the CO2 efflux recovered to pre-crustivory levels. Our findings suggest that macro-crustivores may play a pivotal role in regulating biocrust functioning, introducing a whole new line of trophic research that may transform our understanding of ecosystems dynamics in drylands.

KW - Biocrust

KW - Carbon cycle

KW - Dryland

KW - Hydrology

KW - Surface roughness

KW - Trophic interaction

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JO - GEODERMA

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ER -

Research@Leibniz University

Crustivorous macro-arthropods regulate the microtopography and carbon dynamics of biological soil crusts

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