Mechanisms of soil organic carbon (SOC) stabilization have been widely studied due to their
relevance in the global carbon cycle. No‐till (NT) has been frequently adopted to sequester …

Conservation agriculture (CA) changes soil properties and processes compared to
conventional agriculture. These changes can, in turn, affect the delivery of ecosystem …

Climate‐smart agriculture (CSA) management practices (eg, conservation tillage, cover
crops, and biochar applications) have been widely adopted to enhance soil organic carbon …

An integrated assessment of the potential of different management practices for mitigating
specific components of the total GHG budget (N 2 O and CH 4 emissions and C …

No‐tillage (NT) has been shown to control soil degradation by impacting soil aggregates (ie,
basic units of soil structure, whose characteristics mediate key soil processes, like carbon …

Soil structure stability and carbon (C) storage play an important role in farmland soil
conservation, nutrient supply potential, and climate change mitigation. Different tillage …

Shifting from high intensity (HT) to intermediate intensity (IT) or no tillage (NT) practices has
been credited as being a promising agricultural management option towards climate change …

This study focuses on the quantification of soil water storage and crop yield under different
tillage systems in dryland semiarid Mediterranean conditions. Three long-term tillage …

Agricultural activities through conventional and intensive practices contribute to climate
change by increasing emission of reactive carbon (C) and nitrogen (N) from soils to the …

Both no-tillage and legume cover crops have been shown to increase soil organic carbon
(SOC) in subtropical soils. However, the mechanisms underpinning management system …