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Soil health is a term used to describe the general state or quality of soil, and in an agroecosystem, soil health can be defined as the ability of the soil to respond to agricultural practices in a way that sustainably supports both agricultural production and the provision of other ecosystem services. Conventional agricultural practices cause deterioration in soil quality, increasing its compaction, water erosion, and salinization and decreasing soil organic matter, nutrient content, and soil biodiversity, which negatively influences the productivity and long-term sustainability of the soil. Currently, there are many evidences throughout the world that demonstrate the capability of conservation agriculture (CA) as a sustainable system to overcome these adverse effects on soil health, to avoid soil degradation and to ensure food security. CA has multiple beneficial effects on the physical, chemical, and biological properties of soil. In addition, CA can reduce the negative impacts of conventional agricultural practices on soil health while conserving the production and provision of soil ecosystem services. Today, agricultural development is facing unprecedented challenges, and CA plays a significant role in the sustainability of intensive agriculture. This review will discuss the impact of conservation agricultural practices on soil health and their role in agricultural sustainability.

AbstractThe impact of different arable farming practices on soil erosion is only partly resolved, and the effect of conservation tillage practices in organic agriculture on sediment loss has rarely been tested in the field. This study investigated rainfall-induced interrill sediment loss in a long-term replicated arable farming system and tillage experiment (the FAST trial) with four different cropping systems: (1) organic farming with intensive tillage, (2) organic farming with reduced tillage, (3) conventional farming with intensive tillage, and (4) conventional farming with no tillage. Measurements were carried out under simulated heavy rainfall events with runoff plots in 2014 (fallow land after winter wheat) and 2017 (during maize growth). Organic farming decreased mean sediment delivery compared to conventional farming by 30% (0.54 t ha−1 h−1). This study demonstrated that reduced tillage in organic farming decreased sediment delivery (0.73 t ha−1 h−1) compared to intensively tilled organic plots (1.87 t ha−1 h−1) by 61%. Nevertheless, the combination of conventional farming and no tillage showed the lowest sediment delivery (0.24 t ha−1 h−1), whereas intensively tilled conventional plots revealed the highest delivery (3.46 t ha−1 h−1). Erosion rates were much higher in June during maize growth (2.92 t ha−1 h−1) compared to those of fallow land after winter wheat (0.23 t ha−1 h−1). Soil surface cover and soil organic matter were the best predictors for reduced sediment delivery, and living plant cover from weeds in reduced organic treatments appeared to protect soil surfaces better than plant residues in conventional, no-tillage plots. Soil erosion rates were significantly lower when soil cover was above 30%. In conclusion, this study demonstrates that both organic farming and conservation agriculture reduce soil losses and showed for the first time that reduced tillage practices are a major improvement in organic farming when it comes to soil erosion control.

Conservation agriculture, which is based on minimum tillage, permanent soil cover and crop rotations, has widely been promoted as a practice to maintain or improve soil quality and enhance crop productivity. To a large extent, the beneficial effects of conservation agriculture are expected to be provided by permanent soil cover with crop residues. Surface crop residues play an important role for crop growth through their benefits on soil-related structural components and processes in the agro-ecosystem, referred to in this study as agro-ecological functions. Through a meta-analysis of the literature, we have studied the relative effects of surface crop residue levels on the performance of a set of agro-ecological functions compared with a no-till bare soil, i.e., without surface residues. The selected agro-ecological functions were soil water evaporation control, soil water infiltration, soil water runoff control, soil loss control, soil nutrient availability, soil organic carbon (SOC) stocks and gains, weed control and soil meso- and macrofauna abundance. The potential effects of crop residue cover were quantified using boundary line models. Our main findings were (1) 8 t ha −1 of residues were needed to decrease soil water evaporation by about 30% compared to no-till bare soil. (2) To achieve the maximum effect on soil water infiltration, water runoff and soil loss control, residue amounts of at least 2 t ha −1 were required. (3) The effect of increasing the amounts of surface crop residues on soil nutrient supply (N, P and K) was relatively low; the boundary line models were not significant. (4) The average annual SOC gain increased with increasing amounts of residues, with a mean of 0.38 t C ha −1  year −1 with 4 to 5 t ha −1 of residues. (5) Weed emergence and biomass can be reduced by 50% compared to a no-till bare soil with residue amounts of 1 t ha −1 or more. (6) There was a weak response in soil meso- and macrofauna abundance to increasing amounts of surface crop residues. The maximum effect corresponded to an increase of 45% compared to a no-till bare soil and was reached from 10 t ha −1 of residues. Our findings suggest that optimal amounts of surface residues in the practice of conservation agriculture will largely depend on the type of constraints to crop production which can be addressed with mulching.

Climate change poses serious risks to Indian agriculture as half of the agricultural land of the country is rainfed. Climate change affects crop yield, soil processes, water availability, and pest dynamics. Several adaptation strategies such as heat- and water stress-tolerant crop varieties, stress-tolerant new crops, improved agronomic management practices, improved water use efficiency, conservation agriculture practices and improved pest management, improved weather forecasts, and other climate services are in place to minimize the climatic risks. The agriculture sector contributes 14% of the greenhouse gas (GHG) from the country. Mitigation of GHG emission from agriculture can be achieved by changing land-use management practices and enhancing input-use efficiency. Experiments in India showed that methane emission from lowland rice fields can be reduced by 40–50% with alternate wetting and drying (AWD), growing shorter duration varieties, and using neem-coated urea according to soil health card (SHC) and leaf color chart (LCC). Dry direct-seeding of rice, which does not require continuous soil submergence, can reduce methane emission by 70–75%. Sequestration of carbon (C) in agricultural soil can be promoted with the application of organic manure, crop residues, and balanced nutrients. India has taken several proactive steps for addressing the issues of climate change in agriculture. Recently, it has also committed for reducing GHG emission intensity by 45% by 2030 and achieving net zero emission by 2070. The paper discusses the major impacts of climate change, potential adaptation, and mitigation options and the initiatives of Govt. of India in making Indian agriculture climate-smart.

  Conservation agriculture is often assumed to reduce soil N 2 O emissions. Yet, studies analyzing the specific effect of conservation agriculture practices on N 2 O emissions give contradictory results. Herein, we synthesized a comprehensive database on the three main conservation agriculture practices (cover crops, diversified crop rotations, and no-till and/or reduced tillage (NT/RT)) to elucidate the role of conservation practices on N 2 O emissions. Further, we used a random meta-forest approach to identify the most important predictors of the effects of these practices on soil N 2 O emissions. Averaged across all comparisons, NT/RT significantly decreased soil N 2 O emissions by 11% (95% CI: –19 to –1%) compared to conventional tillage. The reductions due to NT/RT were more commonly observed in humid climates and in soils with an initial carbon content < 20 g kg –1 . The implementation of cover crops and diversified crop rotations led to variable effects on soil N 2 O emissions. Cover crops were more likely to reduce soil N 2 O emissions at neutral soil pH, and in soils with intermediate carbon (~20 g kg –1 ) and nitrogen (~3 g kg –1 ) contents. Diversified crop rotations tended to increase soil N 2 O emissions in temperate regions and neutral to alkaline soils. Our results provide a comprehensive predictive framework to understand the conditions in which the adoption of various conservation agriculture practices can contribute to climate change mitigation. Combining these results with a similar mechanistic understanding of conservation agriculture impacts on ecosystem services and crop production will pave the way for a wider adoption globally of these management practices.

Black soil conservation has attracted increasing attention from researchers. However, few studies have addressed black soil degradation and conservation mechanisms in the black soil region of Northeast China. In this study, we investigated black soil in Bei’an City in Heilongjiang Province and conducted comparisons with soil in other locations with similar environmental conditions and agricultural production levels but different reclamation histories. We predicted and analyzed the changes in the organic matter and nitrogen contents of black soils after different numbers of years under reclamation by using a gray forecast model. In addition, we aimed to identify soil conservation practices that consider the physical, chemical, and microbial properties of soils in the black soil region of Northeast China for implementation in the long term. The results showed that human and natural factors, such as long-term unsustainable cultivation practices and soil erosion, have caused the structural degradation of black soil in Northeast China. The annual decreases in the organic matter and nitrogen contents of black soil in Bei’an City were determined as 0.17% and 0.18%, respectively, using the gray forecast model. Preliminarily explorations identified the potential mechanisms associated with the effects of soil conservation practices on the organic matter and nitrogen contents, and microbial dynamics in black soils. Finally, according to the current implementation of black soil conservation practices in the black soil region of Northeast China, the outlook for future soil conservation practices is reasonable. This study provides a theoretical reference to meet the aims of protection and utilization for black soil in Northeast China in the future.

Water scarcity is an escalating global concern that poses significant challenges to agriculture. The need to feed a growing population, coupled with changing climate patterns, demands a re-evaluation of water use efficiency in major field crops. Water efficiency in agriculture is a critical facet of sustainable water management in rural areas, where agriculture often serves as a primary economic activity. In rural regions, where water resources are often limited, efficient agricultural water management is vital to ensure food security, economic stability, and environmental sustainability. In this review, we have discussed various measures to improve water use efficiency or productivity in agricultural systems. Adopting the strategies for enhancing water productivity at plant and field level may include: rain water harvesting in rural area, soil moisture conservation practices like mulching, crop residue retention and conservation agriculture, better utilization of stored soil moisture by best crop management interventions, irrigation scheduling, integrated farming systems i.e. multiple usage of water in agriculture by combining various farm enterprises like crop production, dairy and fishery. Beside these, reviewed the water use efficiency for important field crops around the world. Review also discussed about how beneficial public policies particularly watershed management in rural area are needed to establish the right socioeconomic conditions for boosting WUE in the agriculture.

In the Mediterranean region, the long-term provision of agro-ecosystem services is threatened by accelerating climate change, unsustainable farming practices, and other pressures. Alternative management practices such as conservation agriculture could be expected to ensure sustainability of ecosystem services from Mediterranean agro-ecosystems. Conservation agriculture is characterized by minimal soil disturbance, permanent soil cover, and diversification of crop species. We analyzed the impacts of several forms of alternative agricultural management practices (conservation tillage, cover cropping, mulching, manual weed management, organic fertilizer use, no-irrigation system) on multiple ecosystem services based on 155 published case studies (1994–2015). The effect size of various management options on four provisioning and four regulating ecosystem services were quantified. Impacts of conservation management options are not uniform. All regulating services were positively affected by the conservation management options except for the system without irrigation. In contrast, the provisioning services were inconsistently influenced by the conservation management options. For crop yield, environmentally sustainable soil management was beneficial, but organic fertilization (effect size = − 0.17), manual weed management (effect size = − 0.35), and no-irrigation system (effect size = − 0.5) led to lower crop yields. The impact on crop biomass was mainly negative but not significant. Water availability was especially important to enhance both provisioning and regulating services. Overall, alternative agriculture management practices led to more positive than negative effects on ecosystem services in the study region. Stimulating the application of conservation management practices is therefore an important policy option for decision-makers given the vulnerability of ecosystem services in the Mediterranean basin.