Your search keyword '"Soil carbon management"' showing total 7 results

1. Mineral-mediated stability of organic carbon in soil and relevant interaction mechanisms

Author

Zibo Xu and Daniel C.W. Tsang

Subjects

Carbon stability, Mineral transformation, Carbon sequestration, Bio-geochemistry, Soil carbon management, Sustainable waste management, Ecology, QH540-549.5, Environmental sciences, GE1-350

Abstract

Soil, the largest terrestrial carbon reservoir, is central to climate change and relevant feedback to environmental health. Minerals are the essential components that contribute to over 60% of soil carbon storage. However, how the interactions between minerals and organic carbon shape the carbon transformation and stability remains poorly understood. Herein, we critically review the primary interactions between organic carbon and soil minerals and the relevant mechanisms, including sorption, redox reaction, co-precipitation, dissolution, polymerization, and catalytic reaction. These interactions, highly complex with the combination of multiple processes, greatly affect the stability of organic carbon through the following processes: (1) formation or deconstruction of the mineral–organic carbon association; (2) oxidative transformation of the organic carbon with minerals; (3) catalytic polymerization of organic carbon with minerals; and (4) varying association stability of organic carbon according to the mineral transformation. Several pieces of evidence related to the carbon turnover and stability during the interaction with soil minerals in the real eco-environment are then demonstrated. We also highlight the current research gaps and outline research priorities, which may map future directions for a deeper mechanisms-based understanding of the soil carbon storage capacity considering its interactions with minerals.

Published

2024

2. Comparative analysis of soil organic matter fractions, lability, stability ratios, and carbon management index in various land use types within bharatpur catchment, Chitwan District, Nepal

Author

Yves Theoneste Murindangabo, Marek Kopecký, Trong Nghia Hoang, Jaroslav Bernas, Tulsi Parajuli, Suman Dhakal, Petr Konvalina, Jean de Dieu Marcel UFITIKIREZI, Gisele Kaneza, Babu Ram Khanal, Shiva Chandra Dhakal, and Arjun Kumar Shrestha

Subjects

Soil carbon pools, Soil carbon management, Soil degradation indicators, Land use/Land cover change, Soil organic matter fractions, Environmental sciences, GE1-350

Abstract

Abstract Background Land use and land cover changes have a significant impact on the dynamics of soil organic matter (SOM) and its fractions, as well as on overall soil health. This study conducted in Bharatpur Catchment, Chitwan District, Nepal, aimed to assess and quantify variations in total soil organic matter (TSOMC), labile organic matter fraction (CL), stable organic matter fraction (CS), stability ratio (SR), and carbon management index (CMI) across seven land use types: pastureland, forestland, fruit orchards, small-scale conventional agricultural land, large-scale conventional agricultural land, large-scale alternative fallow and conventional agricultural land, and organic farming agricultural land. The study also explored the potential use of the Carbon Management Index (CMI) and stability ratio (SR) as indicators of soil degradation or improvement in response to land use changes. Results The findings revealed significant differences in mean values of TSOMC, CL, and CS among the different land use types. Forestland and organic farming exhibited significantly higher TSOMC (3.24%, 3.12%) compared to fruit orchard lands (2.62%), small scale conventional farming (2.22%), alternative fallow and conventional farming (2.06%), large scale conventional farming (1.84%) and pastureland (1.20%). Organic farming and Forestland also had significantly higher CL (1.85%, 1.84%) and CS (1.27%, 1.39%) compared to all other land use types. Forest and organic farming lands showed higher CMI values, while pastures and forests exhibited higher SR values compared to the rest of the land use types. Conclusions This study highlights the influence of various land use types on soil organic matter pools and demonstrates the potential of CMI and SR as indicators for assessing soil degradation or improvement in response to land use and land cover changes.

Published

2023

3. Comparative analysis of soil organic matter fractions, lability, stability ratios, and carbon management index in various land use types within bharatpur catchment, Chitwan District, Nepal.

Author

Murindangabo, Yves Theoneste, Kopecký, Marek, Hoang, Trong Nghia, Bernas, Jaroslav, Parajuli, Tulsi, Dhakal, Suman, Konvalina, Petr, UFITIKIREZI, Jean de Dieu Marcel, Kaneza, Gisele, Khanal, Babu Ram, Dhakal, Shiva Chandra, and Shrestha, Arjun Kumar

Subjects

*LAND use, *SOIL testing, *AGRICULTURAL exhibitions, *ORGANIC farming, *ORGANIC compounds, *LAND cover

Abstract

Background: Land use and land cover changes have a significant impact on the dynamics of soil organic matter (SOM) and its fractions, as well as on overall soil health. This study conducted in Bharatpur Catchment, Chitwan District, Nepal, aimed to assess and quantify variations in total soil organic matter (TSOMC), labile organic matter fraction (CL), stable organic matter fraction (CS), stability ratio (SR), and carbon management index (CMI) across seven land use types: pastureland, forestland, fruit orchards, small-scale conventional agricultural land, large-scale conventional agricultural land, large-scale alternative fallow and conventional agricultural land, and organic farming agricultural land. The study also explored the potential use of the Carbon Management Index (CMI) and stability ratio (SR) as indicators of soil degradation or improvement in response to land use changes. Results: The findings revealed significant differences in mean values of TSOMC, CL, and CS among the different land use types. Forestland and organic farming exhibited significantly higher TSOMC (3.24%, 3.12%) compared to fruit orchard lands (2.62%), small scale conventional farming (2.22%), alternative fallow and conventional farming (2.06%), large scale conventional farming (1.84%) and pastureland (1.20%). Organic farming and Forestland also had significantly higher CL (1.85%, 1.84%) and CS (1.27%, 1.39%) compared to all other land use types. Forest and organic farming lands showed higher CMI values, while pastures and forests exhibited higher SR values compared to the rest of the land use types. Conclusions: This study highlights the influence of various land use types on soil organic matter pools and demonstrates the potential of CMI and SR as indicators for assessing soil degradation or improvement in response to land use and land cover changes. [ABSTRACT FROM AUTHOR]

Published

2023

4. Mineral-mediated stability of organic carbon in soil and relevant interaction mechanisms.

Author

Xu Z and Tsang DCW

Abstract

Soil, the largest terrestrial carbon reservoir, is central to climate change and relevant feedback to environmental health. Minerals are the essential components that contribute to over 60% of soil carbon storage. However, how the interactions between minerals and organic carbon shape the carbon transformation and stability remains poorly understood. Herein, we critically review the primary interactions between organic carbon and soil minerals and the relevant mechanisms, including sorption, redox reaction, co-precipitation, dissolution, polymerization, and catalytic reaction. These interactions, highly complex with the combination of multiple processes, greatly affect the stability of organic carbon through the following processes: (1) formation or deconstruction of the mineral-organic carbon association; (2) oxidative transformation of the organic carbon with minerals; (3) catalytic polymerization of organic carbon with minerals; and (4) varying association stability of organic carbon according to the mineral transformation. Several pieces of evidence related to the carbon turnover and stability during the interaction with soil minerals in the real eco-environment are then demonstrated. We also highlight the current research gaps and outline research priorities, which may map future directions for a deeper mechanisms-based understanding of the soil carbon storage capacity considering its interactions with minerals., Competing Interests: The authors declare no conflicts of interest., (© 2024 The Author(s).)

Published

2024

5. Barriers to and opportunities for the uptake of soil carbon management practices in European sustainable agricultural production

Author

Mills, Jane, Ingram, Julie, Dibari, Camilla, Merante, Paolo, Karaczun, Zbigniew, Molnar, Andras, Sánchez, Berta, Iglesias, Ana, Ghaley, Bhim Bahadur, Mills, Jane, Ingram, Julie, Dibari, Camilla, Merante, Paolo, Karaczun, Zbigniew, Molnar, Andras, Sánchez, Berta, Iglesias, Ana, and Ghaley, Bhim Bahadur

Abstract

Soil carbon management practices are those that add and maintain organic carbon in the soil. These agricultural practices can potentially both contribute to climate change mitigation and increase the soil’s resilience to physical and biological stresses. The paper draws on research findings from five regions across Europe to identify regionally-specific barriers to and opportunities for the adoption of soil carbon management practices. Data were derived from 50 interviews with policy-makers and advisers and 5 stakeholder workshops in Denmark, Italy, Hungary, Poland and Spain. Several barriers to the uptake of soil carbon management practices were common across all regions, however, regional variations were also identified highlighting the importance of understanding the context into which these practices are introduced. Key barriers related to existing biophysical conditions, lack of financial support, farmer knowledge and experience, and the quality of the advisory service. Opportunities included providing economic incentives, harmonizing regulation, supporting long term thinking and planning for resilience and providing good quality advice. We conclude that in addition to persuasive mechanisms for encouraging the adoption of these practices, what is required is a more process-oriented approach that focuses on a series of experiential changes and fosters farmer learning through interactive models of communicative intervention.

Published

2020

6. Barriers to and opportunities for the uptake of soil carbon management practices in European sustainable agricultural production

Author

Andras Molnar, Paolo Merante, Bhim Bahadur Ghaley, Zbigniew M. Karaczun, Berta Sánchez, Camilla Dibari, Ana Iglesias, Julie Ingram, and Jane Mills

Subjects

Soil carbon management, barriers, opportunities, sustainable agriculture, climate change mitigation, media_common.quotation_subject, barriers, Context (language use), 010501 environmental sciences, Development, 01 natural sciences, S589.75_Agriculture, 12. Responsible consumption, climate change mitigation, opportunities, 11. Sustainability, Sustainable agriculture, Soil carbon management, Agricultural productivity, Environmental planning, 0105 earth and related environmental sciences, media_common, 2. Zero hunger, Renewable Energy, Sustainability and the Environment, Stakeholder, 04 agricultural and veterinary sciences, Soil carbon, 15. Life on land, sustainable agriculture, Climate change mitigation, Incentive, 13. Climate action, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Psychological resilience, Business, Agronomy and Crop Science

Abstract

Soil carbon management practices are those that add and maintain organic carbon in the\ud soil. These agricultural practices can potentially both contribute to climate change\ud mitigation and increase the soil's resilience to physical and biological stresses. The paper\ud draws on research findings from five regions across Europe to identify regionally-specific\ud barriers to and opportunities for the adoption of soil carbon management practices. Data\ud were derived from 50 interviews with policy-makers and advisers and 5 stakeholder\ud workshops in Denmark, Italy, Hungary, Poland and Spain. Several barriers to the uptake of\ud soil carbon management practices were common across all regions, however, regional\ud variations were also identified highlighting the importance of understanding the context\ud into which these practices are introduced. Key barriers related to existing biophysical\ud conditions, lack of financial support, farmer knowledge and experience, and the quality of\ud the advisory service. Opportunities included providing economic incentives, harmonising\ud regulation, supporting long term thinking and planning for resilience and providing good\ud quality advice. We conclude that in addition to persuasive mechanisms for encouraging the\ud adoption of these practices, what is required is a more process-oriented approach that\ud focuses on a series of experiential changes and fosters farmer learning through interactive\ud models of communicative intervention.

Published

2020

7. Diversification and ecosystem services for conservation agriculture: Outcomes from pastures and integrated crop–livestock systems

Author

Sanderson, Matt A., Archer, David, Hendrickson, John, Kronberg, Scott, Liebig, Mark, Nichols, Kris, Schmer, Marty, Tanaka, Don, Aguilar, Jonathan, Sanderson, Matt A., Archer, David, Hendrickson, John, Kronberg, Scott, Liebig, Mark, Nichols, Kris, Schmer, Marty, Tanaka, Don, and Aguilar, Jonathan

Abstract

Conservation agricultural systems rely on three principles to enhance ecosystem services: (1) minimizing soil disturbance, (2) maximizing soil surface cover and (3) stimulating biological activity. In this paper, we explore the concept of diversity and its role in maximizing ecosystem services from managed grasslands and integrated agricultural systems (i.e., integrated crop–livestock–forage systems) at the field and farm level.We also examine trade-offs that may be involved in realizing greater ecosystem services. Previous research on livestock production systems, particularly in pastureland, has shown improvements in herbage productivity and reduced weed invasion with increased forage diversity but little response in terms of animal production. Managing forage diversity in pastureland requires new tools to guide the selection and placement of plant mixtures across a farm according to site suitability and the goals of the producer. Integrated agricultural systems embrace the concept of dynamic cropping systems, which incorporates a long-term strategy of annual crop sequencing that optimizes crop and soil use options to attain production, economic and resource conservation goals by using sound ecological management principles. Integrating dynamic cropping systems with livestock production increases the complexity of management, but also creates synergies among system components that may improve resilience and sustainability while fulfilling multiple ecosystem functions. Diversified conservation agricultural systems can sustain crop and livestock production and provide additional ecosystem services such as soil C storage, efficient nutrient cycling and conservation of biodiversity.

Published

2013