The fate of rice crop residues and context-dependent greenhouse gas emissions: Model-based insights from Eastern India

Sonam Sherpa virender kumar Andrew Mcdonald (2024, [Artículo])

Crop residue burning is a common practice in many parts of the world that causes air pollution and greenhouse gas (GHG) emissions. Regenerative practices that return residues to the soil offer a ‘no burn’ pathway for addressing air pollution while building soil organic carbon (SOC). Nevertheless, GHG emissions in rice-based agricultural systems are complex and difficult to anticipate, particularly in production contexts with highly variable hydrologic conditions. Here we predict long-term net GHG fluxes for four rice residue management strategies in the context of rice-wheat cropping systems in Eastern India: burning, soil incorporation, livestock fodder, and biochar. Estimations were based on a combination of Tier 1, 2, and 3 modelling approaches, including 100-year DNDC simulations across three representative soil hydrologic categories (i.e., dry, median, and wet). Overall, residue burning resulted in total direct GHG fluxes of 2.5, 6.1, and 8.7 Mg CO2-e in the dry, median, and wet hydrologic categories, respectively. Relative to emissions from burning (positive values indicate an increase) for the same dry to wet hydrologic categories, soil incorporation resulted in a −0.2, 1.8, or 3.1 Mg CO2-e change in emissions whereas use of residues for livestock fodder increased emissions by 2.0, 2.1, or 2.3 Mg CO2-e. Biochar reduced emissions relative to burning by 2.9 Mg CO2-e in all hydrologic categories. This study showed that the production environment has a controlling effect on methane and, therefore, net GHG balance. For example, wetter sites had 2.8–4.0 times greater CH4 emissions, on average, than dry sites when rice residues were returned to the soil. To effectively mitigate burning without undermining climate change mitigation goals, our results suggest that geographically-target approaches should be used in the rice-based systems of Eastern India to incentivize the adoption of regenerative ‘no burn’ residue management practices.

Soil Carbon Rice Residue Burning Life Cycle Assessment CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA SOIL CARBON RICE LIFE CYCLE GREENHOUSE GASES CLIMATE CHANGE

Editorial: Evolution of abiotic stress responses in land plants

Ana Luisa Garcia-Oliveira (2023, [Artículo])

Land Plants Molecular Responses Plant Stress Biology CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA ABIOTIC STRESS TERRESTRIAL PLANTS CLIMATE CHANGE

Carbon credits from agriculture

A G ADEETH CARIAPPA (2023, [Objeto de congreso])

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CARBON AGRICULTURE CLIMATE CHANGE MITIGATION POLICIES

Chapter 22. Heat and climate change mitigation

Fatima Camarillo-Castillo (2022, [Capítulo de libro])

Leaf Epicuticular Wax Source and Sink Relationships CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE CHANGE MITIGATION RESPIRATION HEAT SHOCK ETHYLENE

Colaboración y co-creación de conocimiento para una agricultura sostenible

Jelle Van Loon (2021, [Objeto de congreso])

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA SUSTAINABLE AGRICULTURE AGRIFOOD SYSTEMS FOOD SECURITY CLIMATE CHANGE ADAPTATION

Análisis de la disminución de emisiones de CO2 en el acondicionamiento de un espacio con un sistema pasivo

JULIO CESAR BRITO REYNA (2023, [Tesis de maestría])

En el contexto global de la dependencia de fuentes de energía fósil en el modelo energético actual, la electricidad desempeña un papel fundamental en el crecimiento y desarrollo de las ciudades. Derivado del consumo excesivo de estas fuentes, se genera la presencia de fenómenos como el Cambio Climático, evidenciando así el uso generalizado de sistemas de climatización en edificaciones durante la temporada de verano en áreas geográficas con climas tropicales y cálidos.

El trabajo presenta un estudio comparativo anual de los impactos ambientales de dos sistemas de climatización en un espacio construido previamente: un sistema activo y un sistema pasivo. El estudio se llevó a cabo mediante la simulación de procesos sustentables utilizando el software TRNSYS® y también se evaluaron los indicadores de Calentamiento Global, Agotamiento de la Capa de Ozono y Agotamiento de combustibles fósiles, por mencionar a algunos, utilizando la metodología de Análisis de Ciclo de Vida (ACV) en el software OpenLCA. Los resultados demuestran una reducción de los impactos ambientales mediante el uso de elementos pasivos en comparación con el uso de dos aires acondicionados y su consumo eléctrico, evitando una huella de carbono de un 98% en su etapa de construcción y hasta en un 100% en su etapa de operación.

Este estudio contribuye al conocimiento sobre la importancia de implementar estrategias de climatización pasiva en edificaciones existentes como una alternativa sostenible y de bajo impacto ambiental. Los hallazgos respaldan la necesidad de promover soluciones más eficientes y respetuosas con el medio ambiente en el sector de la climatización, en línea con la transición hacia un modelo energético más sostenible y la mitigación del Cambio Climático.

In the global context of dependence on fossil fuel energy sources in the current energy model, electricity plays a crucial role in the growth and development of cities. This is evident in the widespread use of air conditioning systems in buildings during the summer season in areas with tropical and warm climates.

This work presents an annual comparative study of the environmental impacts of two cooling systems in a pre-existing space: the active system and the passive system. The study was carried out through the simulation of sustainable processes using the TRNSYS® software, and various indicators such as Global Warming Potential (GWP100a), Ozone Depletion Potential, and Fossil Fuel Depletion were evaluated using the Life Cycle Assessment (LCA) methodology in the OpenLCA software. The results demonstrate a reduction in environmental impacts through the use of passive elements compared to the use of two air conditioning units and their electricity consumption, avoiding a carbon footprint of 98% during its construction stage and up to 100% during its operational stage

This study contributes to the understanding of the importance of implementing passive cooling strategies in existing buildings as a sustainable and low-impact alternative. The findings support the need to promote more efficient and environmentally-friendly solutions in the cooling sector, in line with the transition towards a more sustainable energy model and the mitigation of Climate Change.

INGENIERÍA Y TECNOLOGÍA CIENCIAS TECNOLÓGICAS Energía electrica, climatización, sustentabilidad, Cambio Climático Electricity, cooling, sustainability, Climate Change

CCAFS Outcome Synthesis Report:

Mathieu Ouédraogo John Recha Maren Radeny Paresh Shirsath Peter Läderach Osana Bonilla-Findji (2021, [Documento de trabajo])

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE-SMART AGRICULTURE INVESTMENT FARMING SYSTEMS CLIMATE CHANGE

Impacts of climate change on agriculture and household welfare in Zambia: an economy-wide analysis

Hambulo Ngoma (2023, [Objeto de congreso])

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE CHANGE SMALLHOLDERS ECONOMIC ANALYSIS

The impact of 1.5 °C and 2.0 °C global warming on global maize production and trade

Wei Xiong Tariq Ali (2022, [Artículo])

Future Climate Scenario Data Yield Reduction Risk CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE CHANGE GREENHOUSE EFFECT MAIZE MITIGATION SIMULATION ACCLIMATIZATION ADAPTATION GLOBAL WARMING

Review of Nationally Determined Contributions (NCD) of Kenya from the perspective of food systems

Tek Sapkota (2023, [Documento de trabajo])

Agriculture is one of the fundamental pillars of the 2022–2027 Bottom-up Economic Transformation Plan of the Government of Kenya for tackling complex domestic and global challenges. Kenya's food system is crucial for climate change mitigation and adaptation. Kenya has prioritized aspects of agriculture, food, and land use as critical sectors for reducing emissions towards achieving Vision 2030's transformation to a low-carbon, climate-resilient development pathway. Kenya's updated NDC, as well as supporting mitigation and adaptation technical analysis reports and other policy documents, has identified an ambitious set of agroecological transformative measures to promote climate-smart agriculture, regenerative approaches, and nature-positive solutions. Kenya is committed to implementing and updating its National Climate Change Action Plans (NCCAPs) to present and achieve the greenhouse gas (GHG) emission reduction targets and resilience outcomes that it has identified.

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE CHANGE GREENHOUSE GAS EMISSIONS FOOD SYSTEMS LAND USE CHANGE AGRICULTURE POLICIES DATA ANALYSIS FOOD WASTES