It’s Time to Give Up on Breeder Reactors

Cochran, Thomas B.; Feiveson, Harold A.; Миан, Зиа; Ramana, M. V.; Schneider, Mycle; Hippel, Frank N. von

doi:10.2968/066003007

Cited by 14 publications

(13 citation statements)

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“…The neutrons propagating the chain reaction remain energetic, or fast. Fast reactors are more flexible in the type of fuel they can consume and can, for example, use uranium-238 as fuel, which is 140 times more abundant than uranium-235 (Cochran et al 2010). 4.…”

Section: Notesmentioning

confidence: 99%

“…5 Expert reviews, though, have also found technical problems with fast reactors, in particular sodium leaks, which, while not deadly, have made past reactors prone to shutdowns, which increases the cost of electricity produced (Pillai and Ramana 2014). And though liquid sodium has some safety advantages as a coolant, it also reacts violently with water and burns if exposed to air; liquid-sodium-cooled fast reactors have been shut down for long periods by sodium fires (Cochran et al 2010). The problems could get even more serious.…”

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confidence: 99%

“…Whether such an explosive core disassembly could release enough energy to rupture a reactor containment and cause a Chernobyl-scale release of radioactivity into the environment is a major concern and subject of debate. (Cochran et al 2010) In their paper, they noted that though about $100 billion had been spent globally on breeder reactor research and development and demonstration projects, no one had yet produced a reactor that was economically competitive with a conventional light-water reactor. Japan is the most recent country to show signs of throwing in the towel: In October 2016, it announced that in 2020, it would start decommissioning its Monju fast reactor, which had a troubled history of accidents and cover-ups.…”

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confidence: 99%

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Can North America’s advanced nuclear reactor companies help save the planet?

Eaves¹

2016

Bulletin of the Atomic Scientists

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Section: Notesmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Can North America’s advanced nuclear reactor companies help save the planet?

Eaves¹

2016

Bulletin of the Atomic Scientists

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“…The FBR, however, needs fuel with a much higher concentration of fissile material; 14% is assumed in the MIT study (2011). As an alternative to plutonium, we assume that uranium enriched to 20% (highly enriched uranium [HEU]) could be used to operate these reactors based on Cochran et al (2010). This, however, has been tested on a very limited scale.…”

Section: Performance and Cost Of Technologiesmentioning

confidence: 99%

“…The breeder reactor concept has generally only been tested on a limited scale, but breeding ratios above unity, the production of a greater amount of fissile material than consumed, have been achieved in many countries and reactor types (Cochran, et al 2010). In our model, due to the lack of extensive data related to FBR fuel economy, we assume a breeding ratio of 1 and base our costs on sodium cooled reactors.…”

Section: Performance and Cost Of Technologiesmentioning

confidence: 99%

Nuclear power as a climate mitigation strategy – technology and proliferation risk

Lehtveer

Hedenus

2014

Journal of Risk Research

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Recent years have witnessed renewed interest in nuclear power in large extent due to the need to reduce carbon emissions to mitigate climate change. Most studies of cost and feasibility of stringent climate targets that include nuclear power focus on the currently available light water reactor (LWR) technology. Since climate mitigation requires a long-term commitment, the inclusion of other nuclear technologies such as mixed oxide-fuelled LWRs and fast breeder reactors may better describe the future energy supply options. These different options also entail different nuclear weapon proliferation risks stemming from uranium enrichment or reprocessing of spent fuel. To investigate this relation, we perform a scenario analysis using the global energy transition model. Our results indicate that meeting a scenario with a 430 ppm CO 2 target for 2100 is feasible without the involvement of nuclear power; however the mitigation costs increase by around 20%. Furthermore, a lasting contribution by nuclear power to climate change mitigation can only be achieved by alternative fissile material production methods and global diffusion of nuclear technologies. This in turn bears important implications for the risk of nuclear proliferation for several reasons. First, knowledge and competence in nuclear technology becomes more accessible, leading to the risk of nuclear programmes emerging in states with weaker institutional capacity. Additionally, even if the reprocessing step in a fast breeder cycle proves to be essentially proliferation resistant, the build-up of breeder reactor systems necessitates a long transition period with large-scale use of enrichment technology and its related proliferation risks. Our study does not include the costs posed on society by nuclear accident risk and by the need to upscale safeguards and regulatory capacity to deal with increased proliferation risk.Keywords: nuclear power; energy system model; nuclear weapon proliferation Introduction Recent years have seen growing concern over the possible effects of climate change and the need for immediate action (e.g. World Bank 2012). At the same time renewed interest in nuclear power has been observed among both countries and researchers alike, which the disaster in Fukushima has not significantly curbed (Rogner 2013). The call for an expansion of nuclear power has been to a large extent motivated by the need to reduce carbon emissions to mitigate climate change (e.g. Vaillancourt et al. 2008;Bauer, Brecha, and Luderer 2012). The advantages of nuclear power that are often emphasised are its low lifecycle greenhouse gas (GHG) emissions and base-load power production. To compare these advantages to those of *Corresponding author. Email: mariliis.lehtveer@chalmers.se © 2014 The Author(s). Published by Taylor & Francis. This is an Open Access article. Non-commercial re-use, distribution, and reproduction in any medium, provided the original work is properly attributed, cited, and is not altered, transformed, or built upon in any way, is permitted. The mor...

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Nuclear Power and Sustainability

Verbruggen¹,

Wealer²

2021

The Palgrave Handbook of Global Sustainability

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It’s Time to Give Up on Breeder Reactors

Cited by 14 publications

References 3 publications

Can North America’s advanced nuclear reactor companies help save the planet?

Can North America’s advanced nuclear reactor companies help save the planet?

Nuclear power as a climate mitigation strategy – technology and proliferation risk

Nuclear Power and Sustainability

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