Repositorio Nacional

China is the largest emitter of greenhouse gases (GHG) and one of the countries most affected by climate change. China's food systems are a major contributor to climate change: in 2018, China's food systems emitted 1.09 billion tons of carbondioxide equivalent (CO2eq) GHGs, accounting for 8.2% of total national GHG emissions and 2% of global emissions. According to the Third National Communication (TNC) Report, in 2010, GHG emissions from energy, industrial processes, agriculture, and waste accounted for 78.6%, 12.3%, 7.9%, and 1.2% of total emissions, respectively, (excluding emissions from land use, land-use change and forestry (LULUCF). Total GHG emissions from the waste sector in 2010 were 132 Mt CO2 eq, with municipal solid waste landfills accounting for 56 Mt. The average temperature in China has risen by 1.1°C over the last century (1908–2007), while nationally averaged precipitation amounts have increased significantly over the last 50 years. The sea level and sea surface temperature have risen by 90 mm and 0.9°C respectively in the last 30 years. A regional climate model predicted an annual mean temperature increase of 1.3–2.1°C by 2020 (2.3–3.3°C by 2050), while another model predicted a 1–1.6°C temperature increase and a 3.3–3.7 percent increase in precipitation between 2011 and 2020, depending on the emissions scenario. By 2030, sea level rise along coastal areas could be 0.01–0.16 meters, increasing the likelihood of flooding and intensified storm surges and causing the degradation of wetlands, mangroves, and coral reefs. Addressing climate change is a common human cause, and China places a high value on combating climate change. Climate change has been incorporated into national economic and social development plans, with equal emphasis on mitigation and adaptation to climate change, including an updated Nationally Determined Contribution (NDC) in 2021. The following overarching targets are included in China's updated NDC: • Peaking carbon dioxide emissions “before 2030” and achieving carbon neutrality before 2060. • Lowering carbon intensity by “over 65%” by 2030 from the 2005 level. • Increasing forest stock volume by around 6 billion cubic meters in 2030 from the 2005 level. The targets have come from several commitments made at various events, while China has explained very well the process adopted to produce its third national communication report. An examination of China's NDC reveals that it has failed to establish quantifiable and measurable targets in the agricultural sectors. According to the analysis of the breakdown of food systems and their inclusion in the NDC, the majority of food system activities are poorly mentioned. China's interventions or ambitions in this sector have received very little attention. The adaptation component is mentioned in the NDC, but is not found to be sector-specific or comprehensive. A few studies have rated the Chinese NDC as insufficient, one of the reasons being its failure to list the breakdown of each sector's clear pathway to achieving its goals. China's NDC lacks quantified data on food system sub-sectors. Climate Action Trackers' "Insufficient" rating indicates that China's domestic target for 2030 requires significant improvements to be consistent with the Paris Agreement's target of 1.5°C temperature limit. Some efforts are being made: for example, scientists from the Institute of Environment and Sustainable Development in Agriculture, Chinese Academy of Agricultural Sciences (IEDA-CAAS) have developed methods for calculating GHG emissions from livestock and poultry farmers that have been published as an industrial standard by the Ministry of Agriculture and Rural Affairs, PRC (Prof Hongmin Dong, personal communication) but this still needs to be consolidated and linked to China’s NDC. The updated Nationally Determined Contributions fall short of quantifiable targets in agriculture and food systems as a whole, necessitating clear pathways. China's NDC is found to be heavily focused on a few sectors, including energy, transportation, and urban-rural development. The agricultural sectors' and food systems' targets are vague, and China's agrifood system has a large carbon footprint. As a result, China should focus on managing the food system (production, processing, transportation, and food waste management) to reduce carbon emissions. Furthermore, China should take additional measures to make its climate actions more comprehensive, quantifiable, and measurable, such as setting ambitious and clear targets for the agriculture sector, including activity-specific GHG-reduction pathways; prioritizing food waste and loss reduction and management; promoting sustainable livestock production and low carbon diets; reducing chemical pollution; minimizing the use of fossil fuel in the agri-system and focusing on developing green jobs, technological advancement and promoting climate-smart agriculture; promoting indigenous practices and locally led adaptation; restoring degraded agricultural soils and enhancing cooperation and private partnership. China should also prepare detailed NDC implementation plans including actions and the GHG reduction from conditional targets.

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

Agroecology can promote climate change adaptation outcomes without compromising yield in smallholder systems

Sieglinde Snapp Yodit Kebede Eva Wollenberg (2023, [Artículo])

A critical question is whether agroecology can promote climate change mitigation and adaptation outcomes without compromising food security. We assessed the outcomes of smallholder agricultural systems and practices in low- and middle-income countries (LMICs) against 35 mitigation, adaptation, and yield indicators by reviewing 50 articles with 77 cases of agroecological treatments relative to a baseline of conventional practices. Crop yields were higher for 63% of cases reporting yields. Crop diversity, income diversity, net income, reduced income variability, nutrient regulation, and reduced pest infestation, indicators of adaptative capacity, were associated with 70% or more of cases. Limited information on climate change mitigation, such as greenhouse gas emissions and carbon sequestration impacts, was available. Overall, the evidence indicates that use of organic nutrient sources, diversifying systems with legumes and integrated pest management lead to climate change adaptation in multiple contexts. Landscape mosaics, biological control (e.g., enhancement of beneficial organisms) and field sanitation measures do not yet have sufficient evidence based on this review. Widespread adoption of agroecological practices and system transformations shows promise to contribute to climate change services and food security in LMICs. Gaps in adaptation and mitigation strategies and areas for policy and research interventions are finally discussed.

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE CHANGE CROPS FOOD SUPPLY GAS EMISSIONS GREENHOUSE GASES FARMING SYSTEMS AGROECOLOGY FOOD SECURITY LESS FAVOURED AREAS SMALLHOLDERS YIELDS NUTRIENTS BIOLOGICAL PEST CONTROL CARBON SEQUESTRATION LEGUMES

Farmers′ use of climate change adaptation strategies and their impacts on food security in Kenya

Girma Gezmu Gebre Yuichiro Amekawa Asmiro Abeje Fikadu Dil Bahadur Rahut (2023, [Artículo])

Adaptation Strategies Smallholder Farmers CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA CLIMATE CHANGE FOOD SECURITY SMALLHOLDERS

Addressing agricultural labour issues is key to biodiversity-smart farming

Thomas Daum Frédéric Baudron Matin Qaim Ingo Grass (2023, [Artículo])

There is an urgent need for agricultural development strategies that reconcile agricultural production and biodiversity conservation. This is especially true in the Global South where population growth is rapid and much of the world's remaining biodiversity is located. Combining conceptual thoughts with empirical insights from case studies in Indonesia and Ethiopia, we argue that such strategies will have to pay more attention to agricultural labour dynamics. Farmers have a strong motivation to reduce the heavy toil associated with farming by adopting technologies that save labour but can negatively affect biodiversity. Labour constraints can also prevent farmers from adopting technologies that improve biodiversity but increase labour intensity. Without explicitly accounting for labour issues, conservation efforts can hardly be successful. We hence highlight the need for biodiversity-smart agriculture, that is farming practices or systems that reconcile biodiversity with land and labour productivity. Our empirical insights suggest that technological and institutional options to reconcile farmers' socio-economic goals and biodiversity conservation exist but that more needs to be done to implement such options at scale.

Land Sharing Trade-Offs CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA AGRICULTURAL DEVELOPMENT BIODIVERSITY CONSERVATION LABOUR SUSTAINABILITY

Adaptation to current and future climatic risks in agriculture: Maharashtra, India

Paresh Shirsath Anil Pimpale Pramod Aggarwal (2022, [Libro])

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA RISK CLIMATE RESILIENCE AGRICULTURE CLIMATE CHANGE ADAPTATION

Optimización del proceso de estampado en la empresa Rivian: aplicación del método SMED

Diego Rodríguez Arroyo Luis Alberto Cáceres Díaz ISABEL PEREYRA LAGUNA (2023, [Artículo])

En la era actual, la industria automotriz se encuentra en un estado de transformación constante, impulsado principalmente por la rápida integración de tecnologías emergentes. Aquellas empresas que logran destacar son las que no sólo innovan en diseño y funcionalidad, sino también en la eficiencia productiva. Rivian, una prominente empresa estadounidense especializada en vehículos eléctricos destaca por sus audaces diseños y su compromiso con la sostenibilidad. No obstante, al adentrarse en el funcionamiento interno de sus plantas de producción, surgen ciertos desafíos. En particular, en las instalaciones de la planta de Rivian, se ha detectado que el proceso de estampado, esencial para modelar las piezas de acero de sus vehículos, representa un cuello de botella con gran área de oportunidad que requiere una pronta intervención debido al tiempo muerto que impacta a la producción, entre éstas, la alimentación del material a la prensa de estampado, donde actualmente existen muchas actividades manuales que ocasionan tiempo extra de operación, el cual se puede reducir mediante la automatización de algunas operaciones. En este artículo, se presenta un desarrollo detallado sobre la implementación y optimización del proceso en una prensa de estampado, utilizando la metodología intercambio de troqueles en un solo minuto (SMED por sus siglas en inglés) para maximizar y mejorar la eficiencia de los recursos y satisfacer la demanda de producción. A través de esta herramienta de Manufactura Esbelta, se aplican sistemáticamente las etapas y ciclos del SMED con el objetivo de realizar el cambio de modelo en una maquina en un tiempo objetivo de 12 minutos. Este trabajo de investigación describe una serie de desafíos y las soluciones implementadas en diferentes estaciones de la prensa, buscando incrementar su eficiencia y minimizar los riesgos para los operadores. Además, se enfoca en reducir el material defectuoso producido en la prensa, lo que contribuye a un aumento en la calidad y una disminución en los costos por unidad. Esto tuvo como resultado ahorros de miles de dólares en costos variables de la prensa.

In the current era, the automotive industry is in a state of constant transformation, caused primarily by the rapid integration of emerging technologies. Those companies that can stand out are those that not only innovate in design and functionality but also productive efficiency. Rivian, a prominent American company specializing in electric vehicles, is known for its bold designs and commitment to sustainability. However, when delving into the inner workings of your production plants, certain challenges arise. At the Rivian plant facilities, it has been detected that the stamping process, essential for modeling the steel parts of its vehicles, represents a bottleneck in the process with a large area of opportunity that requires prompt intervention due to high downtime in the press line that impacts production, specifically in the setting of material, there are a lot of manual operations that cause a lot of overtime that can be reduced with automated processes. In this article, a detailed development on the implementation and optimization of the process in a stamping press is presented, using the SMED methodology (Single Minute Exchange Die) to maximize and improve resource efficiency and meet production demand. Through this Lean Manufacturing tool, the stages, and cycles of the SMED are systematically applied to carry out the model change in a machine in a target time of 12 minutes. This research work describes a series of challenges and solutions implemented in different press stations, seeking to increase their efficiency and minimize the risks for operators. Additionally, it focuses on reducing defective material produced on the press, which contributes to an increase in quality and a decrease in unit costs. This resulted in savings of thousands of dollars in variable press costs.

El primer autor agradece el apoyo de CIATEQ y de la empresa y grupo de trabajo en Rivian, que con todo el análisis de datos y la instalación de las diversas mejoras siempre hubo el apoyo y la comunicación correcta como equipo de trabajo. Además de agradecer el gran apoyo del asesor el Dr. Luis Cáceres y la Dra. Isabel Pereyra por su constante retroalimentación y el fuerte apoyo durante estos meses de trabajo en este artículo sobre SMED, mejorando en el análisis y representación de datos ya que con los conocimientos y la experiencia de ambos se facilitó la realización y culminación de este proyecto. De igual manera los autores agradecen a la Revista Politécnica de Aguascalientes por permitir la publicación de este artículo.

Cambio de modelo SMED Automatización Optimización Technology stamping Automation SMED INGENIERÍA Y TECNOLOGÍA CIENCIAS TECNOLÓGICAS OTRAS ESPECIALIDADES TECNOLÓGICAS OTRAS OTRAS

2022 Advanced wheat improvement course: Global wheat rust surveillance

monitoring

David Hodson (2022, [Objeto de congreso])

CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA WHEAT RUSTS DISEASE SURVEILLANCE NEW TECHNOLOGY REMOTE SENSING