Effect of farming system and yield in the life cycle assessment of Jatropha-based bioenergy in Mali

Almeida, Joana; Moonen, Pieter; Soto, Iria; Achten, Wouter; Muys, Bart

doi:10.1016/j.esd.2014.10.001

Cited by 17 publications

(16 citation statements)

References 35 publications

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“…(GHG) emissions of the product system are favorable, that is, making the system an intensive crop, in accordance with what is reported in the literature [69]. These variations affect the energy efficiency of the entire system, because they impact the supply of Jatropha seeds, increasing the demand from 2.65 kg to 3.33 kg of seeds to obtain one kg of oil.…”

Section: Sensitivity Of the Product Systemsupporting

confidence: 71%

“…This implies that at higher fruit yields, the global greenhouse gas The evaluation of the 25% decrease in oil as a sensitivity variable implies that the oil content of the seed would decrease from 40% to 30% in mass fraction, generating a considerable increase in impact (Figure 7), such as the case of the carbon footprint with an elevation of 21%, while the energy footprint is increased by 15%. This implies that at higher fruit yields, the global greenhouse gas (GHG) emissions of the product system are favorable, that is, making the system an intensive crop, in accordance with what is reported in the literature [69]. These variations affect the energy efficiency of the entire system, because they impact the supply of Jatropha seeds, increasing the demand from 2.65 kg to 3.33 kg of seeds to obtain one kg of oil.…”

Section: Sensitivity Of the Product Systemsupporting

confidence: 66%

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Environmental Impact Associated with the Supply Chain and Production of Biodiesel from Jatropha curcas L. through Life Cycle Analysis

et al. 2018

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Abstract:The energy market is diversifying, allowing for the development of biofuels that seek to reduce environmental impact and be energetically competitive with conventional fuels. One of the aforementioned biofuels is the biodiesel that is produced from the oil extracted from the seeds of Jatropha curcas L. This research uses life cycle analysis (LCA) tool to analyze the following environmental impacts associated with its production: energy, water footprint, carbon footprint, mineral resource depletion, fossil resource depletion, terrestrial ecotoxicity, and human toxicity. The following stages were evaluated: (i) cultivation, (ii) the extraction of oil, and (iii) the biodiesel manufacturing process. The results showed that the overall process has an accumulated energy demand of 37.9 MJ/kg biodiesel, and generates 2.16 kg CO 2 eq. of greenhouse gases (GHG) per kg of biofuel. The cultivation stage had the greatest contribution towards its energy and carbon footprints, taking up 45% and 60%, respectively. However, considering the energy valorization of the coproducts that are generated in the agricultural and extraction stages for self-consumption into the product system, both categories of impact mentioned above were reduced by 35% and 41%, respectively.

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Section: Sensitivity Of the Product Systemsupporting

confidence: 71%

Section: Sensitivity Of the Product Systemsupporting

confidence: 66%

Environmental Impact Associated with the Supply Chain and Production of Biodiesel from Jatropha curcas L. through Life Cycle Analysis

et al. 2018

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“…La CompacTropha tiene una capacidad de procesamiento de 180-400 kg /h 2 (Wellman, 2014). Sin embargo, en la refinería registró una capacidad de 125 kg /h, mientras que la literatura registra capacidades de procesamiento entre 35-104 kg/h (Almeida, Moonen, Soto, Achten, & Muys, 2014;Gmünder et al, 2010). Los rendimientos de extracción del AJ fueron de 34,37 l/h, con 0,25 kg de AJ extraídos por kilogramo de semillas.…”

Section: Extracción De Materia Prima Y Transporte De Materia Primaunclassified

“…Los rendimientos de extracción del AJ fueron de 34,37 l/h, con 0,25 kg de AJ extraídos por kilogramo de semillas. Valores similares de 0,29 kg de AJ por kilogramo de semillas son reportados en la literatura (Almeida et al, 2014). A partir de semillas secas se encontró un porcentaje promedio de AJ de 39,54%, con un bajo índice de acidez de 1,21.…”

Section: Extracción De Materia Prima Y Transporte De Materia Primaunclassified

“…Kumar & Sharma, 2008). Sin embargo, el uso de aceite de jatropha para producir electricidad ha despertado un interés creciente dado que es una alternativa potencial para contribuir al desarrollo sostenible en áreas de difícil acceso (Tokunaga & Konan, 2014) y zonas rurales de países en desarrollo (Almeida et al, 2014;Bouffaron et al, 2012;Gmünder et al, 2010;Grimsby et al, 2012;Portugal-Pereira et al, 2015). Aunque, Wouter MJ Achten et al, (2007) indican que todavía hay pocos estudios que analicen su contribución al desarrollo sostenible.…”

Section: Análisis De Ciclounclassified

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Análisis de la sostenibilidad del ciclo de vida de la electricidad a partir del aceite de jatropha, caso de estudio en Ecuador

Mayorga¹,

Alexandra²

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A Life Cycle Energy Assessment for Biogas as Energy Carrier

Cvetković¹,

Popović²,

Novaković³

et al. 2023

A Sustainable Green Future

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Effect of farming system and yield in the life cycle assessment of Jatropha-based bioenergy in Mali

Cited by 17 publications

References 35 publications

Environmental Impact Associated with the Supply Chain and Production of Biodiesel from Jatropha curcas L. through Life Cycle Analysis

Environmental Impact Associated with the Supply Chain and Production of Biodiesel from Jatropha curcas L. through Life Cycle Analysis

Análisis de la sostenibilidad del ciclo de vida de la electricidad a partir del aceite de jatropha, caso de estudio en Ecuador

A Life Cycle Energy Assessment for Biogas as Energy Carrier

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