Carbon dynamics in agricultural greenhouse gas emissions and removals: a comprehensive review
Agriculture is a pivotal player in the climate change narrative, contributing to greenhouse gas (GHG) emissions while offering potential mitigation solutions. This study delved into agriculture’s climate impact. It comprehensively analysed emissions from diverse agricultural sources, carbon sequestr...
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| Published in | Carbon Letters Vol. 34; no. 1; pp. 265 - 289 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
Singapore
Springer Nature Singapore
01.01.2024
한국탄소학회 Springer Nature B.V |
| Subjects | |
| Online Access | Get full text |
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| Abstract | Agriculture is a pivotal player in the climate change narrative, contributing to greenhouse gas (GHG) emissions while offering potential mitigation solutions. This study delved into agriculture’s climate impact. It comprehensively analysed emissions from diverse agricultural sources, carbon sequestration possibilities, and the repercussions of agricultural emissions on climate and ecosystems. The study began by contextualising the historical and societal importance of agricultural GHG emissions within the broader climate change discourse. It then discussed into GHG emitted from agricultural activities, examining carbon dioxide, methane, and nitrous oxide emissions individually, including their sources and mitigation strategies. This research extended beyond emissions, scrutinising their effects on climate change and potential feedback loops in agricultural systems. It underscored the importance of considering both the positive and negative implications of emissions reduction policies in agriculture. In addition, the review explored various avenues for mitigating agricultural emissions and categorised them as sustainable agricultural practices, improved livestock management, and precision agriculture. Within each category, different subsections explain innovative methods and technologies that promise emissions reduction while enhancing agricultural sustainability. Furthermore, the study addressed carbon sequestration and removal in agriculture, focussing on soil carbon sequestration, afforestation, and reforestation. It highlighted agriculture’s potential not only to reduce emissions, but also to serve as a carbon reservoir, lowering overall GHG impact. The research also scrutinised the multifaceted nature of agriculture, examining the obstacles hindering mitigation strategies, including socioeconomic constraints and regulatory hurdles. This study emphasises the need for equitable and accessible solutions, especially for smallholder farmers. It envisioned the future of agricultural emissions reduction, emphasising the advancements in measurement, climate-smart agricultural technologies, and cross-sectoral collaboration. It highlighted agriculture’s role in achieving sustainability and resilience amid a warming world, advocating collective efforts and innovative approaches. In summary, this comprehensive analysis recognised agriculture’s capacity to mitigate emissions while safeguarding food security, biodiversity, and sustainable development. It presents a compelling vision of agriculture as a driver of a sustainable and resilient future.
Graphical abstract |
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| AbstractList | Agriculture is a pivotal player in the climate change narrative, contributing to greenhouse gas (GHG) emissions while offering potential mitigation solutions. This study delved into agriculture’s climate impact. It comprehensively analysed emissions from diverse agricultural sources, carbon sequestration possibilities, and the repercussions of agricultural emissions on climate and ecosystems. The study began by contextualising the historical and societal importance of agricultural GHG emissions within the broader climate change discourse. It then discussed into GHG emitted from agricultural activities, examining carbon dioxide, methane, and nitrous oxide emissions individually, including their sources and mitigation strategies. This research extended beyond emissions, scrutinising their effects on climate change and potential feedback loops in agricultural systems. It underscored the importance of considering both the positive and negative implications of emissions reduction policies in agriculture. In addition, the review explored various avenues for mitigating agricultural emissions and categorised them as sustainable agricultural practices, improved livestock management, and precision agriculture. Within each category, different subsections explain innovative methods and technologies that promise emissions reduction while enhancing agricultural sustainability. Furthermore, the study addressed carbon sequestration and removal in agriculture, focussing on soil carbon sequestration, afforestation, and reforestation. It highlighted agriculture’s potential not only to reduce emissions, but also to serve as a carbon reservoir, lowering overall GHG impact. The research also scrutinised the multifaceted nature of agriculture, examining the obstacles hindering mitigation strategies, including socioeconomic constraints and regulatory hurdles. This study emphasises the need for equitable and accessible solutions, especially for smallholder farmers. It envisioned the future of agricultural emissions reduction, emphasising the advancements in measurement, climate-smart agricultural technologies, and cross-sectoral collaboration. It highlighted agriculture’s role in achieving sustainability and resilience amid a warming world, advocating collective efforts and innovative approaches. In summary, this comprehensive analysis recognised agriculture’s capacity to mitigate emissions while safeguarding food security, biodiversity, and sustainable development. It presents a compelling vision of agriculture as a driver of a sustainable and resilient future. Agriculture is a pivotal player in the climate change narrative, contributing to greenhouse gas (GHG) emissions while offering potential mitigation solutions. This study delved into agriculture’s climate impact. It comprehensively analysed emissions from diverse agricultural sources, carbon sequestration possibilities, and the repercussions of agricultural emissions on climate and ecosystems. The study began by contextualising the historical and societal importance of agricultural GHG emissions within the broader climate change discourse. It then discussed into GHG emitted from agricultural activities, examining carbon dioxide, methane, and nitrous oxide emissions individually, including their sources and mitigation strategies. This research extended beyond emissions, scrutinising their effects on climate change and potential feedback loops in agricultural systems. It underscored the importance of considering both the positive and negative implications of emissions reduction policies in agriculture. In addition, the review explored various avenues for mitigating agricultural emissions and categorised them as sustainable agricultural practices, improved livestock management, and precision agriculture. Within each category, different subsections explain innovative methods and technologies that promise emissions reduction while enhancing agricultural sustainability. Furthermore, the study addressed carbon sequestration and removal in agriculture, focussing on soil carbon sequestration, afforestation, and reforestation. It highlighted agriculture’s potential not only to reduce emissions, but also to serve as a carbon reservoir, lowering overall GHG impact. The research also scrutinised the multifaceted nature of agriculture, examining the obstacles hindering mitigation strategies, including socioeconomic constraints and regulatory hurdles. This study emphasises the need for equitable and accessible solutions, especially for smallholder farmers. It envisioned the future of agricultural emissions reduction, emphasising the advancements in measurement, climate-smart agricultural technologies, and cross-sectoral collaboration. It highlighted agriculture’s role in achieving sustainability and resilience amid a warming world, advocating collective efforts and innovative approaches. In summary, this comprehensive analysis recognised agriculture’s capacity to mitigate emissions while safeguarding food security, biodiversity, and sustainable development. It presents a compelling vision of agriculture as a driver of a sustainable and resilient future. Graphical abstract Agriculture is a pivotal player in the climate change narrative, contributing to greenhouse gas (GHG) emissions while offering potential mitigation solutions. This study delved into agriculture’s climate impact. It comprehensively analysed emissions from diverse agricultural sources, carbon sequestration possibilities, and the repercussions of agricultural emissions on climate and ecosystems. The study began by contextualising the historical and societal importance of agricultural GHG emissions within the broader climate change discourse. It then discussed into GHG emitted from agricultural activities, examining carbon dioxide, methane, and nitrous oxide emissions individually, including their sources and mitigation strategies. This research extended beyond emissions, scrutinising their effects on climate change and potential feedback loops in agricultural systems. It underscored the importance of considering both the positive and negative implications of emissions reduction policies in agriculture. In addition, the review explored various avenues for mitigating agricultural emissions and categorised them as sustainable agricultural practices, improved livestock management, and precision agriculture. Within each category, different subsections explain innovative methods and technologies that promise emissions reduction while enhancing agricultural sustainability. Furthermore, the study addressed carbon sequestration and removal in agriculture, focussing on soil carbon sequestration, afforestation, and reforestation. It highlighted agriculture’s potential not only to reduce emissions, but also to serve as a carbon reservoir, lowering overall GHG impact. The research also scrutinised the multifaceted nature of agriculture, examining the obstacles hindering mitigation strategies, including socioeconomic constraints and regulatory hurdles. This study emphasises the need for equitable and accessible solutions, especially for smallholder farmers. It envisioned the future of agricultural emissions reduction, emphasising the advancements in measurement, climate-smart agricultural technologies, and cross-sectoral collaboration. It highlighted agriculture’s role in achieving sustainability and resilience amid a warming world, advocating collective efforts and innovative approaches. In summary, this comprehensive analysis recognised agriculture’s capacity to mitigate emissions while safeguarding food security, biodiversity, and sustainable development. It presents a compelling vision of agriculture as a driver of a sustainable and resilient future. KCI Citation Count: 0 |
| Author | Yusuf, Mohammad SaberiKamarposhti, Morteza Kamyab, Hesam Hashim, Haslenda |
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| Snippet | Agriculture is a pivotal player in the climate change narrative, contributing to greenhouse gas (GHG) emissions while offering potential mitigation solutions.... |
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| SubjectTerms | Adaptation Agricultural ecosystems Agricultural management Agricultural practices Agricultural production Agricultural technology Agriculture Agroforestry Biodiversity Carbon dioxide Carbon sequestration Carbon sources Characterization and Evaluation of Materials Chemistry and Materials Science Climate change Climate effects Climate-smart agriculture Emission measurements Emissions Emissions control Energy consumption Farming systems Feedback loops Fermentation Food Food security Greenhouse effect Greenhouse gases Impact analysis Land use Livestock Manures Materials Engineering Materials Science Mitigation Nanotechnology Nitrous oxide Precision agriculture Reduction Reforestation Resilience Review Small farms Sustainability Sustainable agriculture Sustainable development Sustainable practices Trends 자연과학일반 |
| TableOfContents | Carbon dynamics in agricultural greenhouse gas emissions and removals: a comprehensive review Abstract Graphical abstract 1 Introduction 1.1 Background and importance of agriculture-related GHG emissions 1.2 The need for a comprehensive analysis 2 GHG emissions in agricultural production 2.1 CO emissions 2.1.1 Energy use in agriculture 2.1.2 Land use changes 2.2 CH emissions 2.2.1 Enteric fermentation in livestock 2.2.2 Manure management 2.3 N O emissions 2.3.1 Fertiliser application 2.3.2 Soil management practices 3 Sources and drivers of agricultural emissions 3.1 Livestock production 3.1.1 Ruminant vs. non-ruminant emissions 3.1.2 Factors influencing emissions 3.2 Crop agriculture 3.2.1 Fertiliser types and application methods 3.2.2 Tillage practices 3.3 Land use changes and deforestation 3.3.1 Conversion of forests to agricultural land 3.3.2 Peatland drainage and emissions 4 Impacts of agricultural emissions 4.1 Climate change effects 4.1.1 Global warming potential of different gases 4.1.2 Regional and local climate impacts 4.2 Feedback loops 4.2.1 Implications for agriculture itself 5 Mitigation strategies for agricultural emissions 5.1 Sustainable agricultural practices 5.1.1 Conservation agriculture 5.1.2 Agroforestry 5.1.3 Cover crops 5.2 Improved livestock management 5.2.1 Dietary interventions 5.2.2 Manure management techniques 5.3 Precision agriculture 5.3.1 Nutrient management 5.3.2 Emission-reducing technologies 6 Carbon sequestration and removal in agriculture 6.1 Soil carbon sequestration 6.1.1 Enhancing soil organic matter 6.1.2 Role of agroecosystems 6.2 Afforestation and reforestation 6.2.1 Agroforestry systems 6.2.2 Carbon stocks in tree plantations 7 Challenges and barriers to mitigation 7.1 Socioeconomic constraints 7.1.1 Smallholder farmers 7.1.2 Access to technology 7.2 Policy and regulatory challenges 7.2.1 Land use planning 7.2.2 Incentive mechanisms 8 Synergies and trade-offs in agricultural emissions reduction 8.1 Food security and emissions reductions 8.2 Sustainable development goals alignment 8.3 Biodiversity conservation 9 Future outlook and research directions 9.1 Advancements in emission measurement and monitoring 9.2 Climate-smart agriculture innovations 9.3 Cross-sectoral collaboration 10 Conclusions Acknowledgements References |
| Title | Carbon dynamics in agricultural greenhouse gas emissions and removals: a comprehensive review |
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