1 / 25

Nuclear power: the security dimension

Nuclear power: the security dimension. Dr Stuart Parkinson. www.sgr.org.uk. Some context…. Climate change By 2100, potentially more rapid change than at any time in human history Major threat to water, food, health, shelter…

wynter-haney
Download Presentation

Nuclear power: the security dimension

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Nuclear power: the security dimension Dr Stuart Parkinson www.sgr.org.uk

  2. Some context… • Climate change • By 2100, potentially more rapid change than at any time in human history • Major threat to water, food, health, shelter… • At least 61 states at risk of armed conflict related to climate change • Most vulnerable are least responsible for the problem • Nuclear non-proliferation treaty • Current deadlock over disarmament • Without progress, global regulation of nuclear power will suffer • Rising religious fundamentalism • Can affect both terrorist groups and some governments

  3. In a world such as this, should we expand or phase out nuclear power?

  4. Nuclear weapons proliferation • Many overlaps between civilian and military nuclear technologies/ materials/ skills, for example: • Uranium enrichment • Civilian use: 3-5% U-235 • Military use: ~90% U-235 • Plutonium from reprocessing nuclear waste • Proliferation risk is greater from plutonium • On average ~300kg plutonium produced per modern power station per year – reprocessing would yield enough to make up to 40 nuclear bombs

  5. Nuclear bomb dropped on Nagasaki • 9 August, 1945 • ~6 kg of plutonium • equivalent to 21,000,000 kg of TNT • Heat, blast and radiation killed at least 70,000 people • from population of 200,000 • Almost all buildings within 1½ miles of ‘ground zero’ destroyed

  6. NW proliferation: risks • More civilian nuclear facilities increases potential for diversion to weapons • Determined states which have access to civilian nuclear programme are hard to stop going military • Terrorists interested in stealing fissile material • International Atomic Energy Agency (Regulator) • complaints of lack of resources • also has a role promoting nuclear power • Will the nuclear non-proliferation treaty hold?

  7. NW proliferation: examples • Diversion of civilian nuclear know-how to create Pakistan’s nuclear weapons • Current concerns over Iran’s nuclear power programme

  8. The role of the UK • UK is very influential country • Member of UN Security Council, G8, EU, Head of Commonwealth • UK plans to retain its nuclear weapons • UK go-ahead for new nuclear power sends strong message on climate, energy and security strategy • Also, can the UK keep its own plutonium secure for next 100+ years?

  9. Plutonium-MOX economy? • Use of MOX fuel (part plutonium) in nuclear reactors to prolong uranium supplies • presence of plutonium leads to increased risk of proliferation • Potential for move to ‘Generation IV’ reactors completely fuelled by plutonium • even greater proliferation risk

  10. Security & safety of nuclear facilities • Risk of major nuclear ‘incident’ is very low, but… • Terrorist groups consider nuclear facilities as potential targets • ‘Successful’ attack on high-level waste/ plutonium store could be worse than Chernobyl • Even a ‘failed’ attack could cause major disruption

  11. Labour’s think-tank • “Not only does more civil nuclear activity mean more nuclear weapons related materials being available to potentially fall into the hands of terrorists or rogue states worldwide, but reactors, waste sites and reprocessing plants themselves are also possible terrorist targets which, if hit, could lead to massive loss of life and economic disruption”

  12. Are the climate benefits of nuclear good enough to offset the security concerns?

  13. Nuclear power and carbon emissions • Nuclear fuel cycle • uranium mining + milling • UF6 conversion • U-235 fuel enrichment • nuclear fuel fabrication • fuel transportation • reactor operation • waste encapsulation • waste transportation • future waste disposal

  14. CO2 emissions especially depend on • uranium ore grade • as grade declines, energy consumption/ carbon emissions rise • uranium ore type • U-235 enrichment method • future nuclear waste plans • eg underground repository • also • construction of power station

  15. Estimated Nuclear CO2 Emissions Source: House of Commons Environmental Audit Committee (2006)

  16. Even if low carbon… Sustainable Development Commission: • Replacement nuclear programme would only lead to 4% cut in CO2 emissions from 1990 levels • Not realised until at least 2024 • “A new nuclear power programme could divert public funding away from more sustainable technologies that will be needed regardless, hampering other long term efforts to move to a low carbon economy with diverse energy sources”

  17. Renewable energy Wind Bioenergy Solar Hydro Wave Tidal Geothermal Energy efficiency Combined heat & power (CHP) Building insulation Efficient lighting Efficient appliances Efficient vehicles What are the alternatives? • Carbon capture and storage • ‘burial’ of carbon from fossil fuels • Controlling demand • Behaviour change

  18. Energy efficiency • 30% of UK’s overall energy supply dumped as waste heat/ hot water from power stations • more than 10 times energy produced by nuclear power • Combined heat & power (CHP) • UK: 7% of electricity • Netherlands: 30% • Denmark: 50%

  19. Case 1 - Tyndall Centre study • Non-nuclear path to reduce UK carbon emissions by ~85% by 2050 • Energy consumption down by ~40% by 2050 due to efficiency technologies & behaviour change (driven by economic reform) • Strong support for R&D of renewables, carbon capture & storage, hydrogen fuel cells

  20. Case 2 – CAT study • Non-nuclear path to reduce UK carbon emissions by ~100% by 2027 • Energy consumption down by ~50% by 2027 due to efficiency technologies & behaviour change – including wide use of Tradable Carbon Quotas • Strong support for R&D of renewables & energy storage (but reliance on expanding existing and near-term technologies)

  21. The role of R&D • To realise the scale of emissions reduction necessary to tackle climate change, we need serious funding of non-nuclear energy R&D – especially renewable energy

  22. Source: IEA (2001)

  23. Source: IEA (2006)

  24. Conclusions • Nuclear power creates serious security problems • Major factors affecting global security over coming decades are likely to greatly increase these problems • Low-carbon benefits of nuclear are not great enough to outweigh drawbacks • Alternatives have great potential to reduce carbon emissions without nuclear security risks

  25. References

More Related