Biochar Implementation in Rice Paddies for Addressing Greenhouse Gas Emissions and Nutrient Loss: A Review

Saikanth, D. R. K.; Singh, Bal Veer; Kumar, Avinash; Kumar, Uttam; Surender,; Yadav, Babita; Singh, Onkar

doi:10.9734/ijpss/2023/v35i183326

Cited by 4 publications

(1 citation statement)

References 20 publications

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“…According to a study by Singh et al (2023), soils treated with biochar emit considerably less N 2 O than unamended soils. By serving as a physical barrier, the adsorption capabilities of biochar can aid in lowering CH 4 emissions from paddy fields (Saikanth et al 2023).…”

Section: Biocharmentioning

confidence: 99%

Carbon Sequestration through Organic Amendments, Clay Mineralogy and Agronomic Practices: A Review

Shivangi,

Singh,

Shahi

et al. 2024

Egypt.J. Soil Sci.

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ARBON sequestration (CS) is a significant method for reducing climate change (CC) and enhancing soil fertility in agriculture. Many people are becoming increasingly worried about climate change, and researchers have been studying soils as a way to store CO 2 . Due to their significance in regulating the global carbon cycle, the methods of soil organic carbon (SOC) stabilization have recently garnered considerable interest. SOC dynamics, focusing on how clay mineralogy affects soil retention and stabilization. Understanding how SOC stabilization works can help in implementing effective management practices for storing soil organic matter (SOM), improving soil structure, and reducing greenhouse gas emissions. The effectiveness of SOC sequestration depends on the amount and quality of SOM, soil type, topography, mineral type, and CC. Soil carbon has been lost as a result of inadequate crop and soil management strategies. Over the world, 456 Pg of soil carbon is stored in dead organic matter and above-ground vegetation, compared to 1417 Pg in the first meter of soil. The agricultural sector is accountable for 25-30% of total worldwide greenhouse gas (GHG) emissions in the form of CO 2 , N 2 O, and CH 4 . Soils that have a lot of organic matter can store more CO 2 , hence having healthy soils can assist in combating climate change. In addition, to sequester SOC, it is important to use organic materials like manure, minerals found in soil, different types of compost, poultry waste, incorporating leftover plant parts, biochar, and proper farming methods like covering the soil with mulch, planting cover crops, managing nutrients, and using mulch effectively. These methods help increase the amount of organic matter in the soil, improve its physical and chemical characteristics, and help the soil store more carbon, which ultimately helps with carbon sequestration and mitigating climate change.

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Section: Biocharmentioning

confidence: 99%

Carbon Sequestration through Organic Amendments, Clay Mineralogy and Agronomic Practices: A Review

Shivangi,

Singh,

Shahi

et al. 2024

Egypt.J. Soil Sci.

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Biochar-assisted remediation of contaminated soils under changing climate

Hameed,

Abbas,

Khan

et al. 2024

Biochar-Assisted Remediation of Contaminated Soils Under Changing Climate

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Nanotechnological Innovations for Soil Pollution Remediation and Environmental Conservation

Singh,

Shahi

et al. 2024

Advances in Environmental Engineering and Green Technologies

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Globally, soil contamination threatens the ecosystem and human health. Ecological, financial, and efficiency issues plague excavation, chemical, and bioremediation methods. Nanotechnology is a promise for soil remediation, offering advantages over existing approaches. Nanotechnology technologies for soil pollution treatment and environmental conservation are covered in this chapter. It examines heavy metals, organic pollutants, pesticides, and radioactive contamination in soil and the limitations of current remediation methods. The chapter next discusses nanotechnology in soil remediation, including nanoparticles, nanomaterials for adsorption and degradation, nano-bioremediation, and nanosensors for pollution monitoring. Case studies and research show nanotechnology's success in soil remediation. Future nanotechnology for soil remediation views and difficulties highlight the need for more research and development to address scalability, cost-effectiveness, and environmental safety.

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Biochar Implementation in Rice Paddies for Addressing Greenhouse Gas Emissions and Nutrient Loss: A Review

Cited by 4 publications

References 20 publications

Carbon Sequestration through Organic Amendments, Clay Mineralogy and Agronomic Practices: A Review

Carbon Sequestration through Organic Amendments, Clay Mineralogy and Agronomic Practices: A Review

Biochar-assisted remediation of contaminated soils under changing climate

Nanotechnological Innovations for Soil Pollution Remediation and Environmental Conservation

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