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Research output: Contribution to Journal/Magazine › Journal article › peer-review
Research output: Contribution to Journal/Magazine › Journal article › peer-review
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TY - JOUR
T1 - Long-term effects of tillage practices and future climate scenarios on topsoil organic carbon stocks in Lower Austria – a modelling and long-term experiment study
AU - Toth, Marton
AU - Davies, Jess
AU - Quinton, John
AU - Davies, Jennifer
AU - Stumpp, Christine
AU - Klik, Andreas
AU - Mehdi-Schulz, Bano
AU - Strauss, Peter
AU - Liebhard, Gunther
AU - Bartmann, Johannes
AU - Strohmeier, Stefan
PY - 2025/2/28
Y1 - 2025/2/28
N2 - Conservation agriculture, with its reduced soil disturbance and enhanced cover, has the potential to increase carbon storage in the topsoil. However, it remains unclear how various tillage practices alter topsoil organic carbon (SOC) storage in the long-term affected by climate change. This study investigates the impacts of three tillage practices, conventional tillage (CT), mulch tillage (MT), and no-till (NT) on future SOC stocks in the topsoil (0-15 cm), considering climate change scenarios (RCP4.5 and RCP8.5) and local soil erosion effects. Therefore, we calibrated and applied the integrated terrestrial C-N-P cycle model (N14CP) to a long-term study site with a cereal-maize dominant crop rotation in Lower Austria. Our calibration (1994–1995) resulted in a RMSE of 45.3 g m-2 and a PBIAS of 9.6%, while validation (2000–2023) resulted in a RMSE of 103.8 g m-2 and a PBIAS of 3.9%. Long-term simulations indicate that topsoil SOC stocks tend to increase under MT by +309 g m-2 (baseline), +233 g m-2 (RCP4.5), and +148 g m-2 (RCP8.5), under NT by +1,145 g m-2 (baseline), +1,059 g m-2 (RCP4.5), and +961 g m-2 (RPC8.5), but SOC stocks may decrease under CT by -209 g m-2 (baseline), -267 g m-2 (RCP4.5), and -332 g m-2 (RCP8.5) by 2100. In contrast to conventional management, our tested conservation agriculture practices (MT and NT) may both serve as viable options to mitigate climate change and erosion impacts on topsoil organic carbon in comparable agro-ecological settings.
AB - Conservation agriculture, with its reduced soil disturbance and enhanced cover, has the potential to increase carbon storage in the topsoil. However, it remains unclear how various tillage practices alter topsoil organic carbon (SOC) storage in the long-term affected by climate change. This study investigates the impacts of three tillage practices, conventional tillage (CT), mulch tillage (MT), and no-till (NT) on future SOC stocks in the topsoil (0-15 cm), considering climate change scenarios (RCP4.5 and RCP8.5) and local soil erosion effects. Therefore, we calibrated and applied the integrated terrestrial C-N-P cycle model (N14CP) to a long-term study site with a cereal-maize dominant crop rotation in Lower Austria. Our calibration (1994–1995) resulted in a RMSE of 45.3 g m-2 and a PBIAS of 9.6%, while validation (2000–2023) resulted in a RMSE of 103.8 g m-2 and a PBIAS of 3.9%. Long-term simulations indicate that topsoil SOC stocks tend to increase under MT by +309 g m-2 (baseline), +233 g m-2 (RCP4.5), and +148 g m-2 (RCP8.5), under NT by +1,145 g m-2 (baseline), +1,059 g m-2 (RCP4.5), and +961 g m-2 (RPC8.5), but SOC stocks may decrease under CT by -209 g m-2 (baseline), -267 g m-2 (RCP4.5), and -332 g m-2 (RCP8.5) by 2100. In contrast to conventional management, our tested conservation agriculture practices (MT and NT) may both serve as viable options to mitigate climate change and erosion impacts on topsoil organic carbon in comparable agro-ecological settings.
KW - Climate change
KW - Conservation agriculture
KW - Long-term experiment
KW - Lower Austria
KW - N14CP model
KW - soil organic carbon
U2 - 10.1016/j.iswcr.2025.02.011
DO - 10.1016/j.iswcr.2025.02.011
M3 - Journal article
JO - International Soil and Water Conservation Research
JF - International Soil and Water Conservation Research
SN - 2095-6339
ER -