Life-cycle impacts from novel thorium–uranium-fuelled nuclear energy systems

Ashley, S. F.; Fenner, Richard; Nuttall, William J.; Parks, GT

doi:10.1016/j.enconman.2015.04.041

Cited by 23 publications

(13 citation statements)

References 18 publications

(34 reference statements)

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“…Life-cycle environmental emissions associated with thorium production and use in open Th-U-based nuclear fuel cycles were also investigated [4]. A comparative life-cycle analysis (LCA) was performed for the three Th-U based systems using GaBi4 and the EcoInvent database [4]. The LCA considered the construction, operation, and decommissioning of each of the reactor systems including all of the associated facilities of an open fuel cycle.…”

Section: Methodsmentioning

confidence: 99%

“…Further details on this methodology, the underlying data used in this analysis, and all life-cycle impact analysis results are detailed in Ref. [4].…”

Section: Methodsmentioning

confidence: 99%

“…The work centred on assessing various performance indicators spanning material flows, waste composition, economics, emissions, and proliferation resistance. These performance indicators were determined by using the UK National Nuclear Laboratory's fuel cycle modelling code ORION [2,3] and also the life-cycle analysis code GaBi [4]. In addition, background issues surrounding the proliferation resistance of Th-U-based fuels were presented at the UK PONI 2012 Conference [5].…”

Section: Introductionmentioning

confidence: 99%

“…The purpose of the paper is to provide a summary of the project. To serve this end the paper refers to some example results from component studies [3,4], and stresses the over-arching project conclusions.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Technology Assessment of Near-Term Open-Cycle Thorium-Fuelled Nuclear Energy Systems

Nuttall

Ashley

Fenner

et al. 2019

Thorium—Energy for the Future

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As part of the RCUK-India civil nuclear research collaboration, British and Indian researchers have assessed the merits and disadvantages of, and potential for, open-cycle thorium-uranium-fuelled (Th-U-fuelled) nuclear energy systems. The research centred on fuel cycle modelling and life-cycle assessment of three Th-U-fuelled nuclear energy systems and compared these to a reference uranium-fuelled nuclear energy system, all operating with open nuclear fuel cycles. The results indicate that thorium-based fuels offer little benefit over conventional uranium-fuelled approaches for open-cycle nuclear energy production. This paper provides an overview on the project and stresses over-arching conclusions.

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Section: Methodsmentioning

confidence: 99%

“…Further details on this methodology, the underlying data used in this analysis, and all life-cycle impact analysis results are detailed in Ref. [4].…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Technology Assessment of Near-Term Open-Cycle Thorium-Fuelled Nuclear Energy Systems

Nuttall

Ashley

Fenner

et al. 2019

Thorium—Energy for the Future

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“…Then, Data acquisition is required to quantify the input and output flows associated with the power generation technologies listed in Table 1. Inventory data for the new technologies, i.e., those potentially participating in the electricity production mix according to the optimisation of each scenario, are based on specific literature: coal thermal power plants with/without capture [37][38][39], NGCC with/without capture [40,41], nuclear fission (III and IV generation) [42,43], nuclear fusion [44], cogeneration [45], hydropower dam and run-of-river plants [46], wind farms [47,48], tidal power [49], wave power [50], photovoltaics (open-ground and rooftop systems) [51], concentrated solar power plant with/without storage [52,53], geothermal (binary cycle) power plants [54], bioresource technology (biomass integrated gasification combined cycle, biogas and waste-to-energy plants) [55][56][57], PEMFC [58], and SOFC [59]. Finally, data for both existing technologies and background processes are retrieved from the ecoinvent database [60].…”

Section: Electricity Productionmentioning

confidence: 99%

Prospective Analysis of Life-Cycle Indicators through Endogenous Integration into a National Power Generation Model

et al. 2016

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Abstract:Given the increasing importance of sustainability aspects in national energy plans, this article deals with the prospective analysis of life-cycle indicators of the power generation sector through the case study of Spain. A technology-rich, optimisation-based model for power generation in Spain is developed and provided with endogenous life-cycle indicators (climate change, resources, and human health) to assess their evolution to 2050. Prospective performance indicators are analysed under two energy scenarios: a business-as-usual one, and an alternative scenario favouring the role of carbon dioxide capture in the electricity production mix by 2050. Life-cycle impacts are found to decrease substantially when existing fossil technologies disappear in the mix (especially coal thermal power plants). In the long term, the relatively high presence of natural gas arises as the main source of impact. When the installation of new fossil options without CO 2 capture is forbidden by 2030, both renewable technologies and-to a lesser extent-fossil technologies with CO 2 capture are found to increase their contribution to electricity production. The endogenous integration of life-cycle indicators into energy models proves to boost the usefulness of both life cycle assessment and energy systems modelling in order to support decision-and policy-making.

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The theory of inventive problem solving (TRIZ) ‐based strategic mapping of green nuclear energy investments with spherical fuzzy group decision‐making approach

et al. 2021

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Summary The aim of this study is to define strategies to increase green nuclear energy investments. Within this context, a model is suggested that includes two different stages. Firstly, the consensus‐based fuzzy preferences are determined for these investments. For this purpose, four different TRIZ‐based strategies are identified, which have an influence on the effectiveness of these projects. Furthermore, in the second stage, the significance weights of these strategies are calculated by considering the spherical fuzzy DEMATEL approach. The findings indicate that dynamicity is the most appropriate TRIZ strategy for the effectiveness of green nuclear energy investments. In addition, the prior action is another significant strategy that should also be considered in these projects. It is obvious that sufficient technological infrastructure is very important for the performance of green nuclear power plants and there is a rapid development of this technology. Because of this situation, these nuclear power plants should be designed effectively so that they can be adoptable to any changes in the technology. In this scope, qualified personnel should be employed, and communication between departments should be effective and of high quality. With the help of these issues, technological changes can be adopted more easily.

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Life-cycle impacts from novel thorium–uranium-fuelled nuclear energy systems

Cited by 23 publications

References 18 publications

Technology Assessment of Near-Term Open-Cycle Thorium-Fuelled Nuclear Energy Systems

Technology Assessment of Near-Term Open-Cycle Thorium-Fuelled Nuclear Energy Systems

Prospective Analysis of Life-Cycle Indicators through Endogenous Integration into a National Power Generation Model

The theory of inventive problem solving (TRIZ) ‐based strategic mapping of green nuclear energy investments with spherical fuzzy group decision‐making approach

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