Journal article

Drivers of soil respiration across a management intensity gradient in temperate grasslands under drought


Authors listApostolakis, A; Schöning, I; Michalzik, B; Klaus, VH; Boeddinghaus, RS; Kandeler, E; Marhan, S; Bolliger, R; Fischer, M; Prati, D; Hänsel, F; Nauss, T; Hölzel, N; Kleinebecker, T; Schrumpf, M

Publication year2022

Pages101-116

JournalNutrient Cycling in Agroecosystems

Volume number124

Issue number1

ISSN1385-1314

eISSN1573-0867

Open access statusHybrid

DOI Linkhttps://doi.org/10.1007/s10705-022-10224-2

PublisherSpringer


Abstract
Soil respiration is an important pathway of soil organic carbon losses in temperate grasslands; however, it is rarely studied across broad management intensity gradients in a landscape. Using the soda-lime method, we measured in-situ soil CO2 efflux with single measurements of long exposure time (i.e. 3 day long) in 150 grasslands in three German regions in early summer 2018 and 2019. The grasslands ranged from unfertilized and grazed grasslands to intensively fertilized and frequently harvested ones. To assess effects of grazing and fertilization intensities and plant diversity on soil CO2 efflux, we used Structural Equation Modeling to account for direct effects and indirect effects through soil and plant organic matter quantity and quality. Soil CO2 efflux was suppressed by limited water availability caused by naturally occurring droughts in both study years. Under the prevailing environmental conditions, grazing intensity, plant biomass and plant C:N ratio were not related to soil CO2 efflux. In contrast, fertilization intensity was positively associated with soil CO2 efflux (standardized coefficient of net effect: + 0.04 in 2018 and + 0.03 in 2019). This was because fertilization led to lower plant species richness and, thus, to lower C:N ratios in soils, which were associated with higher soil CO2 efflux (plant species richness net effect: -0.09 in 2018 and -0.18 in 2019; soil C:N ratio direct effect: -0.23 in 2018 and -0.33 in 2019). Intensively managed grasslands have higher soil respiration than extensively managed, plant species-rich grasslands even under the extreme conditions of natural droughts.



Citation Styles

Harvard Citation styleApostolakis, A., Schöning, I., Michalzik, B., Klaus, V., Boeddinghaus, R., Kandeler, E., et al. (2022) Drivers of soil respiration across a management intensity gradient in temperate grasslands under drought, Nutrient Cycling in Agroecosystems, 124(1), pp. 101-116. https://doi.org/10.1007/s10705-022-10224-2

APA Citation styleApostolakis, A., Schöning, I., Michalzik, B., Klaus, V., Boeddinghaus, R., Kandeler, E., Marhan, S., Bolliger, R., Fischer, M., Prati, D., Hänsel, F., Nauss, T., Hölzel, N., Kleinebecker, T., & Schrumpf, M. (2022). Drivers of soil respiration across a management intensity gradient in temperate grasslands under drought. Nutrient Cycling in Agroecosystems. 124(1), 101-116. https://doi.org/10.1007/s10705-022-10224-2


Last updated on 2025-10-06 at 11:43