Abstract
Sustainable agricultural management is needed to promote carbon (C) sequestration in soil, prevent loss of soil fertility, and reduce the release of greenhouse gases. However, the influence of agronomic practices on soil C sequestration depends on the existing pedoclimatic features. We characterized the soils of three farms far away each other in the Emilia-Romagna region (Northern Italy): an organic farm in the Northern Apennines, a biodynamic farm, and a conventional farm on the Po Plain. The total, inorganic, and organic carbon in soil, as well as the distinct humic fractions were investigated, analyzing both the elemental and isotopic (13C/12C) composition. In soils, organic matter appears to be variously affected by mineralization processes induced by microorganisms that consume organic carbon. In particular, organic carbon declined in farms located in the plain (e.g., organic carbon down to 0.75 wt%; carbon stock0-30 cm down to 33 Mg/ha), because of the warmer climate and moderately alkaline environment that enhance soil microbial activity. On the other hand, at the mountain farm, the minimum soil disturbance, the cold climate, and the neutral conditions favored soil C sequestration (organic carbon up to 4.42 wt%; carbon stock0-30 cm up to 160 Mg/ha) in humified organic compounds with long turnover, which can limit greenhouse gas emissions into the atmosphere. This work shows the need for thorough soil investigations, to propose tailored best-practices that can reconcile productivity and soil sustainability.
Highlights
Soil organic matter (SOM) plays a crucial role in soil fertility, crop productivity, and agronomic sustainability, as well as in ecosystem stability and mitigation of climate change [1,2,3,4]
Through soil respiration, which includes root and microbial respiration, C can be emitted in the atmosphere as carbon dioxide (CO2), one of the main greenhouse gases (GHGs; [6])
The present study reports the results of the SaveSOC2 (Save Soil Organic Carbon) project, funded by the Rural Development Program (RDP) of the Emilia-Romagna region, to evaluate the quality and quantity of SOM and its potential to sequester C
Summary
Soil organic matter (SOM) plays a crucial role in soil fertility, crop productivity, and agronomic sustainability, as well as in ecosystem stability and mitigation of climate change [1,2,3,4]. As noted above, several factors affect SOM dynamics, and the ability of soil to reach this goal can differ among pedoclimatic and agronomic systems In this framework, the present study reports the results of the SaveSOC2 (Save Soil Organic Carbon) project, funded by the Rural Development Program (RDP) of the Emilia-Romagna region, to evaluate the quality and quantity of SOM and its potential to sequester C. The carbon stock at the 0–30 cm soil depth was calculated for each farm This comprehensive approach allows an evaluation of SOM evolution, and assesses the C sequestration and/or GHG release from the soils under these management systems and environmental conditions
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