GHG Balance of Agricultural Intensification &amp; Bioenergy Production in the Orinoquia Region, Colombia

Ramirez-Contreras, Nidia Elizabeth; Munar-Florez, David Arturo; Hilst, Floor van der; Espinosa, Juan Carlos; Ocampo-Duran, Álvaro; Ruíz-Delgado, Jonathan; Molina-López, Diego L.; Wicke, Birka; Núñez, Jesús Alberto García; Faaij, André

doi:10.3390/land10030289

Cited by 15 publications

(21 citation statements)

References 41 publications

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“…The results of the mitigation potential analysis reported in Ali et al [ 70 ] provides evidence that the adoption of low-emission energy technologies can significantly reduce GHG emissions in developing countries to help meet the 2050 goals. Ramírez-Contreras [ 71 ] found that renewable energy in the form of bioenergy has the potential to reduce fossil fuel dependence in the Orinoquia region of Colombia by 2030, offering the opportunity to slow down the rate of GHG emissions in this region. Moreover, using proper technology platforms (e.g., geospatial technology, and precision agriculture) with perennial bioenergy crops can not only increase feedstock supply for renewable biofuel production but also improve soil health, sequester carbon, and provide habitat for pollinators and other wildlife species [ 66 , 72 , 73 ].…”

Section: Resultsmentioning

confidence: 99%

Contribution of land use practices to GHGs in the Canadian Prairies crop sector

2021

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The global crop sector is estimated to contribute about 10.4% of global GHGs annually. The Canadian crop sector is assessed as adding about 6.5% to total national emissions. These estimates over report the impact of farming as they ignore the complex interaction of cropping with the environment and the role land use, land use change and forestry (LULUCF) play in sequestering carbon. This study quantifies the contribution of land use to GHG emissions and removals in the Canadian Prairies crop sector between 1985 and 2016. The modeling effort explores how different farming practices (i.e., conventional tillage (CT), minimum tillage (MT), zero tillage (ZT), summerfallow, crop rotations, and residue retention) and input usage rates (i.e., fertilizer and fuel) affect GHG emissions in different soil climate zones and provinces in the Prairies region. The adoption of sustainable practices led to an 80% decline in GHG emissions in the crop sector between 1985 and 2016. Since 2005, the baseline for Canada’s Paris commitment, sectoral emissions dropped 53%, more than is required to meet the 2030 target. Most promising, the crop sector was a net GHG sink between 2013 and 2016 in Alberta and between 2006 and 2016 in Saskatchewan. As positive as these developments have been, more can be done by directing research to identify options for reducing GHGs in Manitoba (which made only minimal improvements as farmers there faced conditions requiring continuous use of conventional tillage practices), to explore better nitrogen management (a major continuing source of GHG from cropping) and by searching for low carbon transport options.

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Section: Resultsmentioning

confidence: 99%

Contribution of land use practices to GHGs in the Canadian Prairies crop sector

2021

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“…LCI for the production of RS was obtained for Colombia conditions, in the Orinoquia region [2] . RS production encompasses both cultivation and harvest stages.…”

Section: Life Cycle Inventorymentioning

confidence: 99%

“…Paddy rice and RS were considered as main outputs. Diesel, land, and fertilizer requirements for rice production was obtained from the literature review [2] . Emissions of the agricultural stage was determined according to the IPCC methodology.…”

Section: Life Cycle Inventorymentioning

confidence: 99%

Life cycle inventory data for ethyl levulinate production from Colombian rice straw

Cañon

Sánchez²,

Cobo³

2022

Data in Brief

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“…There are many examples showing how the agriculture and forestry sectors can devise management approaches that enable biomass production and use for energy in conjunction with supply of food, construction timber and other bio‐based products, while avoiding further conversion of natural ecosystems. Principal means include changes in agriculture practices to increase cropping intensities and yields and improve livestock productivity (Andrade et al, 2017; Brinkman et al, 2021; Cassman & Grassini, 2020; de Souza et al, 2019; Gerssen‐Gondelach et al, 2017; Ramírez‐Contreras et al, 2021), forest management practices enabling biomass harvest for energy (Dale et al, 2017; Ghaffariyan et al, 2017; Spinelli, 2019), and changes to industrial processes to improve biomass conversion efficiencies and use residues and waste to meet internal process energy needs and produce fuels, electricity and heat for use outside the industry (Hagman et al, 2018; Isaksson et al, 2012; Negri et al, 2020; Pettersson & Harvey, 2012). Furthermore, new biomass production systems can be integrated with existing agriculture and forestry systems (incl.…”

Section: The Potential Co‐benefits and Adverse Side Effects Of Bioenergy Systemsmentioning

confidence: 99%

Bioenergy for climate change mitigation: Scale and sustainability

et al. 2021

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Many global climate change mitigation pathways presented in IPCC assessment reports rely heavily on the deployment of bioenergy, often used in conjunction with carbon capture and storage. We review the literature on bioenergy use for climate change mitigation, including studies that use top‐down integrated assessment models or bottom‐up modelling, and studies that do not rely on modelling. We summarize the state of knowledge concerning potential co‐benefits and adverse side effects of bioenergy systems and discuss limitations of modelling studies used to analyse consequences of bioenergy expansion. The implications of bioenergy supply on mitigation and other sustainability criteria are context dependent and influenced by feedstock, management regime, climatic region, scale of deployment and how bioenergy alters energy systems and land use. Depending on previous land use, widespread deployment of monoculture plantations may contribute to mitigation but can cause negative impacts across a range of other sustainability criteria. Strategic integration of new biomass supply systems into existing agriculture and forest landscapes may result in less mitigation but can contribute positively to other sustainability objectives. There is considerable variation in evaluations of how sustainability challenges evolve as the scale of bioenergy deployment increases, due to limitations of existing models, and uncertainty over the future context with respect to the many variables that influence alternative uses of biomass and land. Integrative policies, coordinated institutions and improved governance mechanisms to enhance co‐benefits and minimize adverse side effects can reduce the risks of large‐scale deployment of bioenergy. Further, conservation and efficiency measures for energy, land and biomass can support greater flexibility in achieving climate change mitigation and adaptation.

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GHG Balance of Agricultural Intensification & Bioenergy Production in the Orinoquia Region, Colombia

Cited by 15 publications

References 41 publications

Contribution of land use practices to GHGs in the Canadian Prairies crop sector

Contribution of land use practices to GHGs in the Canadian Prairies crop sector

Life cycle inventory data for ethyl levulinate production from Colombian rice straw

Bioenergy for climate change mitigation: Scale and sustainability

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