DOCSLIB.ORG

Common Concerns About Wind Power Common Concerns About Wind Power (2Nd Edn)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Common Concerns About Wind Power Common Concerns About Wind Power (2Nd Edn) 2nd edn, June 2017 Common concerns about wind power Common concerns about wind power (2nd edn) Written and researched by Iain Cox. Centre for Sustainable Energy, June 2017 Written and researched: 2015 The Centre for Sustainable Energy is a national charity committed to ending the misery of cold homes and fighting climate change. We share our knowledge and practical experience to empower people to change the way they think and act about energy. We are based in Bristol although most of our work has relevance and impact across the UK. Our clients and funders include national, regional and local government agencies, energy companies and charitable sources. PHOTOS: istock.com (cover/p4, p2, p94, p126), Shutterstock (p26, p32); pexels.com (p82), Jasja Dekker (p86), Changhua Coast Conservation Action (p104), Rachel Coxcoon (116) OFFICE 3 St Peter’s Court Bedminster Parade Bristol BS3 4AQ PHONE 0117 934 1400 EMAIL [email protected] WEB cse.org.uk TWITTER cse_bristol CHARITY 298740 COMPANY 2219673 FOUNDED 1979 Contents Introduction page 2 1 | Wind turbines and energy payback times page 5 2 | Materials consumption and life cycle impacts of wind power page 11 3 | Wind power costs and subsidies page 19 4 | Efficiency and capacity factors of wind turbines page 27 5 | Intermittency of wind turbines page 33 6 | Offshore wind turbines page 41 7 | Wind power and nuclear power page 47 8 | Public acceptance and community engagement page 59 9 | Wind turbines and property prices page 69 10 | Siting wind farms on ecologically sensitive land page 75 11 | What effect do wind turbines have on wildlife? page 79 12 | Wind turbines and safety page 95 13 | Shadow flicker and epilepsy risk page 101 14 | Wind turbines and noise page 105 15 | Infrasound, ‘wind turbine syndrome’ and other health concerns page 117 16 | Wind farms and radar page 127 Common concerns about wind power, June 2016 1 Introduction | 3 Introduction Welcome to the second edition of the Centre for Equally, keen proponents of wind power are often too Sustainable Energy’s Common Concerns about Wind quick to dismiss any problems raised, levelling the charge Power. The first edition (2011) is our most widely of ‘nimby’ at anyone who speaks out against planned accessed publication both in print and online. It’s developments. While not necessarily willfully dishonest, popularity reflects the need for a document that helps both sides of the debate can be accused of reporting the interested reader, faced with a mass of conflicting expediently to further their point of view. information, to weigh up the likely impacts of wind power in their locality. We hope this update continues to In this updated and extended publication, we hope that provide an independent guide to the issues, backed up pertinent research continues to be presented in a by hundreds of peer-reviewed papers and a dozens of manner that leads to informed discussion. As before, government studies. this edition of Common Concerns about Wind Power relies heavily on academic peer reviewed publications Every chapter from the first edition makes a and expert reports. Reading this is not intended to be reappearance, in many cases supplemented by new the end of an interested person’s research: rather, it evidence that allows us to give more detailed and should encourage further reading around the subject nuanced consideration to those issues. The second and the casting of a critical eye on the source of edition contains several new chapters covering topics information. Casual assertions that unambiguously state that were not being widely discussed when the first wind power is good or bad without any supporting edition was being prepared. evidence should be judged accordingly. As is demonstrated throughout this document, the reality is Of all renewable energy sources, wind power occupies a frequently more complicated than that. The agendas of unique place due to a combination of two attributes: vested interests too often mean these subtleties are lost technological preparedness (wind is still best placed of all and the subject descends into acrimonious debate. existing renewable energy technologies to contribute the electricity needs of the UK whilst simultaneously What this document aims to show is that, implemented reducing its carbon emissions), and the fact that it is as part of a progressive energy portfolio, wind power inherently site specific (making wind turbines strikingly can significantly reduce both the UK’s carbon footprint, visible additions to often previously undeveloped and its dependence on fuel sources that may become landscapes). The increasing presence of wind farms less secure in the future, or that present a costly and across the country means that communities everywhere unacceptably hazardous legacy for future generations. will continue needing to address the issues surrounding wind power. Changes to government planning policy in However, wind power is not appropriate everywhere and 2015 mean that onshore wind developments cannot can impact communities in different ways. We hope now proceed without a site first having been allocated in that, by publishing this research, communities a local or neighbourhood plan. This publication, themselves will engage constructively with the best therefore, should provide a comprehensive grounding in available evidence to judge if there is a place for wind the facts for local authorities and communities as they turbines in their own locality. To empower communities undertake the development of local policies with regards to make these decisions demands a more mature and to wind power and renewable energy in general. responsible approach from the media, the wind industry and pressure groups on both sides of the debate. And of course wind power continues to be a highly contentious and politically charged issue. This is not Rachel Coxcoon, helped by articles in the UK media that continue to Centre for Sustainable Energy, June 2016 repeat misstatements which are clearly contrary to the evidence and can easily be refuted, or by emotive language and the tendency to ‘cherry-pick’ evidence to present a one-sided view. Common concerns about wind power, June 2016 3 Chapter 1 Wind turbines and energy payback times Summary The harnessing of wind for the generation of electricity may rely on a renewable source of energy, but it must also prove to be sustainable. All systems for converting energy into usable forms have energy requirements themselves, where energy must be invested in the myriad activities necessary for extracting and shaping materials, transport of parts and fuel, building and maintaining power plants and associated infrastructure, and decommissioning or upgrading the site. In its very broadest sense, some even include the expenditure of capital and labour as part of the energy investment. The amount of energy involved in the manufacture, construction, operation and decommissioning of wind farms is often voiced as a concern over whether wind turbines should be used at all. Since the capture and generation of any usable form of energy requires energy to be invested, the question is really one of how effectively the generating plant returns energy back to its users (i.e. society) in relation to the energy invested. There are a number of ways of answering this question, but all these methods essentially seek to present information in a way that is useful in understanding how society can obtain sufficient surplus energy to make its investment worthwhile. In every case, the evidence shows that wind turbines perform well in this regard, often being the most effective of the renewable energy sources after hydropower, and in most situations being comparable or superior to conventional thermal electricity generation (i.e. fossil fuel and nuclear power). Overall, wind is relatively effective – for example, modern wind farms on average return 18 times the energy invested in them over their lifetime – but specific cases have returned lower values, and many very high estimates are born of optimistic projections for electrical output or fail to incorporate certain inputs that count as invested energy. Nonetheless, the modern, larger turbines (>1 MW) typically employed in wind farms today will ‘pay back’ the energy invested in less than a year, in some cases in less than six months. Over the remainder of its 20 to 25-year lifespan, the wind turbine will continue to return useful surplus energy in the form of electricity back to society. What is this based on? caused largely by rising levels of greenhouse gases in the atmosphere. The prodigious consumption of fossil fuels Since the Industrial Revolution, the phenomenal growth by humans has been the single largest contributing and development of global society has been a story of factor to rising levels of CO2 (a major greenhouse gas), vast surpluses of energy.1 These surpluses have been and this fact has also made the quest for alternative provided by fossil fuels, and the years since the end of sources of energy even more pressing.3 the second world war have seen explosive growth driven by a global economy underpinned by oil (in later years The current dependency of the world’s economy on oil accompanied by natural gas). As readily available and gas has prompted much debate about when these reserves of oil have been depleted since 1900, this glut resources might run out.2 This is not meant in the purely of available energy has steadily fallen, and the energy literal sense of there being no more oil in the ground, obtained through the extraction, refinement and delivery but instead seeks to asks when society must invest so of oil and gas fuels to where they can be used is now much energy into extracting and delivering oil that the less than half what it used to be only four decades ago, useful energy obtained is no longer worthwhile.
Load more

Recommended publications
  • The Socio-Economic Benefits of Solar and Wind Energy
    Accelerating the Transition to Clean Energy Technologies The Socio-economic Benefits of Solar and Wind Energy MAY 2014 Copyright (c) IRENA 2014 Unless otherwise indicated, material in this publication may be used freely, shared or reprinted, but acknowledgement is requested. This publication should be cited as: IRENA and CEM (2014), ‘The socio-economic benefits of large-scale solar and wind: an econValue report’. About IRENA The International Renewable Energy Agency (IRENA) is an intergovernmental organisation that sup- ports countries in their transition to a sustainable energy future, and serves as the principal platform for international co-operation, a centre of excellence, and a repository of policy, technology, resource and financial knowledge on renewable energy. IRENA promotes the widespread adoption and sustainable use of all forms of renewable energy, including bioenergy, geothermal, hydropower, ocean, solar and wind energy, in the pursuit of sustainable development, energy access, energy security and low-carbon economic growth and prosperity. www.irena.org About CEM The Clean Energy Ministerial (CEM) is a high-level global forum to promote policies and programs that advance clean energy technology, to share lessons learned and best practices, and to encourage the transition to a global clean energy economy. Initiatives are based on areas of common interest among participating governments and other stakeholders. Acknowledgements econValue is a key project of the Multilateral Solar and Wind Working Group, one of the initiatives of the CEM led by Denmark, Germany and Spain. Coordinators: Rabia Ferroukhi, Diala Hawila and Alvaro Lopez-Peña (IRENA), Martin Schöpe and Martha Ekkert (Federal Ministry for Economic Affairs and Energy of Germany (BMWi).
    [Show full text]
  • Analyzing the Energy Industry in United States
    +44 20 8123 2220 [email protected] Analyzing the Energy Industry in United States https://marketpublishers.com/r/AC4983D1366EN.html Date: June 2012 Pages: 700 Price: US$ 450.00 (Single User License) ID: AC4983D1366EN Abstracts The global energy industry has explored many options to meet the growing energy needs of industrialized economies wherein production demands are to be met with supply of power from varied energy resources worldwide. There has been a clearer realization of the finite nature of oil resources and the ever higher pushing demand for energy. The world has yet to stabilize on the complex geopolitical undercurrents which influence the oil and gas production as well as supply strategies globally. Aruvian's R'search’s report – Analyzing the Energy Industry in United States - analyzes the scope of American energy production from varied traditional sources as well as the developing renewable energy sources. In view of understanding energy transactions, the report also studies the revenue returns for investors in various energy channels which manifest themselves in American energy demand and supply dynamics. In depth view has been provided in this report of US oil, electricity, natural gas, nuclear power, coal, wind, and hydroelectric sectors. The various geopolitical interests and intentions governing the exploitation, production, trade and supply of these resources for energy production has also been analyzed by this report in a non-partisan manner. The report starts with a descriptive base analysis of the characteristics of the global energy industry in terms of economic quantity of demand. The drivers of demand and the traditional resources which are used to fulfill this demand are explained along with the emerging mandate of nuclear energy.
    [Show full text]
  • Microgrid Market Analysis: Alaskan Expertise, Global Demand
    Microgrid Market Analysis: Alaskan Expertise, Global Demand A study for the Alaska Center for Microgrid Technology Commercialization Prepared by the University of Alaska Center for Economic Development 2 3 Contents Introduction .................................................................................................................................................. 4 Market Trends ............................................................................................................................................... 5 Major Microgrid Segments ....................................................................................................................... 5 Global demand of microgrids ................................................................................................................... 5 Where does Alaska fit into the picture? Which segments are relevant? ................................................. 7 Remote/Wind-Diesel Microgrids .......................................................................................................... 8 Military Microgrid ................................................................................................................................. 8 Microgrid Resources with Examples in Alaska .............................................................................................. 8 Wind .......................................................................................................................................................... 8 Kotzebue ............................................................................................................................................
    [Show full text]
  • Neural Network Based Microgrid Voltage Control Chun-Ju Huang University of Wisconsin-Milwaukee
    University of Wisconsin Milwaukee UWM Digital Commons Theses and Dissertations May 2013 Neural Network Based Microgrid Voltage Control Chun-Ju Huang University of Wisconsin-Milwaukee Follow this and additional works at: https://dc.uwm.edu/etd Part of the Electrical and Electronics Commons Recommended Citation Huang, Chun-Ju, "Neural Network Based Microgrid Voltage Control" (2013). Theses and Dissertations. 118. https://dc.uwm.edu/etd/118 This Thesis is brought to you for free and open access by UWM Digital Commons. It has been accepted for inclusion in Theses and Dissertations by an authorized administrator of UWM Digital Commons. For more information, please contact [email protected]. NEURAL NETWORK BASED MICROGRID VOLTAGE CONTROL by Chun-Ju Huang A Thesis Submitted in Partial Fulfillment of the Requirements for the Degree of Master of Science in Engineering at The University of Wisconsin-Milwaukee May 2013 ABSTRACT NEURAL NETWORK BASED MICROGRID VOLTAGE CONTROL by Chun-Ju Huang The University of Wisconsin-Milwaukee, 2013 Under the Supervision of Professor David Yu The primary purpose of this study is to improve the voltage profile of Microgrid using the neural network algorithm. Neural networks have been successfully used for character recognition, image compression, and stock market prediction, but there is no directly application related to controlling distributed generations of Microgrid. For this reason the author decided to investigate further applications, with the aim of controlling diesel generator outputs. Firstly, this thesis examines the neural network algorithm that can be utilized for alleviating voltage issues of Microgrid and presents the results. MATLAT and PSCAD are used for training neural network and simulating the Microgrid model respectively.
    [Show full text]
  • Monitoring and Diagnosis Systems to Improve Nuclear Power Plant Reliability and Safety. Proceedings of the Specialists` Meeting
    J — v ft INIS-mf—15B1 7 INTERNATIONAL ATOMIC ENERGY AGENCY NUCLEAR ELECTRIC Ltd. Monitoring and Diagnosis Systems to Improve Nuclear Power Plant Reliability and Safety PROCEEDINGS OF THE SPECIALISTS’ MEETING JOINTLY ORGANISED BY THE IAEA AND NUCLEAR ELECTRIC Ltd. AND HELD IN GLOUCESTER, UK 14-17 MAY 1996 NUCLEAR ELECTRIC Ltd. 1996 VOL INTRODUCTION The Specialists ’ Meeting on Monitoring and Diagnosis Systems to Improve Nuclear Power Plant Reliability and Safety, held in Gloucester, UK, 14 - 17 May 1996, was organised by the International Atomic Energy Agency in the framework of the International Working Group on Nuclear Power Plant Control and Instrumentation (IWG-NPPCI) and the International Task Force on NPP Diagnostics in co-operation with Nuclear Electric Ltd. The 50 participants, representing 21 Member States (Argentina, Austria, Belgium, Canada, Czech Republic, France, Germany, Hungary, Japan, Netherlands, Norway, Russian Federation, Slovak Republic, Slovenia, Spain, Sweden, Switzerland, Turkey, Ukraine, UK and USA), reviewed the current approaches in Member States in the area of monitoring and diagnosis systems. The Meeting attempted to identify advanced techniques in the field of diagnostics of electrical and mechanical components for safety and operation improvements, reviewed actual practices and experiences related to the application of those systems with special emphasis on real occurrences, exchanged current experiences with diagnostics as a means for predictive maintenance. Monitoring of the electrical and mechanical components of systems is directly associated with the performance and safety of nuclear power plants. On-line monitoring and diagnostic systems have been applied to reactor vessel internals, pumps, safety and relief valves and turbine generators. The monitoring techniques include nose analysis, vibration analysis, and loose parts detection.
    [Show full text]
  • Renewable Energy Annual Review 2 0 1 6 Renewable Energy November 2 0 1 6 • Annual Review
    RENEWABLE ENERGY ANNUAL REVIEW 2 0 1 6 RENEWABLE ENERGY NOVEMBER 2 0 1 6 • ANNUAL REVIEW Published by Financier Worldwide 23rd Floor, Alpha Tower Suffolk Street, Queensway Birmingham B1 1TT United Kingdom Telephone: +44 (0)845 345 0456 Fax: +44 (0)121 600 5911 Email: info@financierworldwide.com www.financierworldwide.com Copyright © 2016 Financier Worldwide All rights reserved. Annual Review • November 2016 Renewable Energy No part of this publication may be copied, reproduced, transmitted or held in a retrievable system without the written permission of the publishers. Whilst every effort is made to ensure the accuracy of all material published in Financier Worldwide, the publishers accept no responsibility for any errors or omissions, nor for any claims made as a result of such errors or omissions. Views expressed by contributors are not necessarily those of the publisher. Any statements expressed by professionals in this publication are understood to be general opinions and should not be relied upon as legal or financial advice. Opinions expressed herein do not necessarily represent the views of the author’s firm or clients or of any organisations of which the author is a member. RENEWABLE ENERGY NOVEMBER 2 0 1 6 • ANNUAL REVIEW Financier Worldwide canvasses the opinions of leading professionals around the world on the latest trends in renewable energy. Contents UNITED STATES ..................................................... 06 Todd E. Alexander CHADBOURNE & PARKE LLP CANADA ............................................................... 10 Scott Whitby FASKEN MARTINEAU DUMOULIN LLP CHILE .................................................................... 14 Gonzalo Jiménez CARIOLA, DÍEZ, PÉREZ-COTAPOS & CÍA LTDA UNITED KINGDOM ................................................ 18 Munir Hassan CMS CAMERON MCKENNA LLP PORTUGAL ............................................................ 22 Ricardo Andrade Amaro MORAIS LEITÃO, GALVÃO TELES, SOARES DA SILVA & ASSOCIADOS JAPAN ..................................................................
    [Show full text]
  • Jacobson and Delucchi (2009) Electricity Transport Heat/Cool 100% WWS All New Energy: 2030
    Energy Policy 39 (2011) 1154–1169 Contents lists available at ScienceDirect Energy Policy journal homepage: www.elsevier.com/locate/enpol Providing all global energy with wind, water, and solar power, Part I: Technologies, energy resources, quantities and areas of infrastructure, and materials Mark Z. Jacobson a,n, Mark A. Delucchi b,1 a Department of Civil and Environmental Engineering, Stanford University, Stanford, CA 94305-4020, USA b Institute of Transportation Studies, University of California at Davis, Davis, CA 95616, USA article info abstract Article history: Climate change, pollution, and energy insecurity are among the greatest problems of our time. Addressing Received 3 September 2010 them requires major changes in our energy infrastructure. Here, we analyze the feasibility of providing Accepted 22 November 2010 worldwide energy for all purposes (electric power, transportation, heating/cooling, etc.) from wind, Available online 30 December 2010 water, and sunlight (WWS). In Part I, we discuss WWS energy system characteristics, current and future Keywords: energy demand, availability of WWS resources, numbers of WWS devices, and area and material Wind power requirements. In Part II, we address variability, economics, and policy of WWS energy. We estimate that Solar power 3,800,000 5 MW wind turbines, 49,000 300 MW concentrated solar plants, 40,000 300 MW solar Water power PV power plants, 1.7 billion 3 kW rooftop PV systems, 5350 100 MW geothermal power plants, 270 new 1300 MW hydroelectric power plants, 720,000 0.75 MW wave devices, and 490,000 1 MW tidal turbines can power a 2030 WWS world that uses electricity and electrolytic hydrogen for all purposes.
    [Show full text]
  • Renewable Energy in Alaska WH Pacific, Inc
    Renewable Energy in Alaska WH Pacific, Inc. Anchorage, Alaska NREL Technical Monitor: Brian Hirsch NREL is a national laboratory of the U.S. Department of Energy, Office of Energy Efficiency & Renewable Energy, operated by the Alliance for Sustainable Energy, LLC. Subcontract Report NREL/SR-7A40-47176 March 2013 Contract No. DE-AC36-08GO28308 Renewable Energy in Alaska WH Pacific, Inc. Anchorage, Alaska NREL Technical Monitor: Brian Hirsch Prepared under Subcontract No. AEU-9-99278-01 NREL is a national laboratory of the U.S. Department of Energy, Office of Energy Efficiency & Renewable Energy, operated by the Alliance for Sustainable Energy, LLC. National Renewable Energy Laboratory Subcontract Report 15013 Denver West Parkway NREL/SR-7A40-47176 Golden, Colorado 80401 March 2013 303-275-3000 • www.nrel.gov Contract No. DE-AC36-08GO28308 This publication was reproduced from the best available copy submitted by the subcontractor and received minimal editorial review at NREL. NOTICE This report was prepared as an account of work sponsored by an agency of the United States government. Neither the United States government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States government or any agency thereof.
    [Show full text]
  • TB Pickens Misadventure with Wind
    T. Boone’s Windy Misadventure And the Global Backlash Against Wind Energy By Robert Bryce Posted on Jul. 28, 2011 Three years ago this month, T. Boone Pickens launched a multi-million dollar crusade to bring more wind energy to the US. “Building new wind generation facilities,” along with energy efficiency and more consumption of domestic natural gas, the Dallas billionaire claimed, would allow the US to “replace more than one-third of our foreign oil imports in 10 years.” Those were halcyon times for the wind industry. These days, Pickens never talks about wind. He’s focused instead on getting a fat chunk of federal subsidies so he can sell more natural gas to long-haul truckers through his company, Clean Energy Fuels. (Pickens and his wife, Madeleine, own about half of the stock of Clean Energy, a stake worth about $550 million.) While the billionaire works the halls of Congress seeking a subsidy of his very own, he's also trying to find a buyer for the $2 billion worth of wind turbines he contracted for back in 2008. The last news report that I saw indicated that he was trying to foist the turbines off onto the Canadians. Being dumped by Pickens is only one of a panoply of problems facing the global wind industry. Among the issues: an abundance of relatively cheap natural gas, a growing backlash against industrial wind projects due to concerns about visual blight and noise, increasing concerns about the murderous effect that wind turbines have on bats and birds, the extremely high costs of offshore wind energy, and a new study which finds that wind energy’s ability to cut carbon dioxide emissions have been overstated.
    [Show full text]
  • Community Energy White Paper April 2014 Contents
    Community Energy White Paper April 2014 Contents Letter from the CEO .............................................................................. 3 Executive Summary ............................................................................. 4 Redefining energy ............................................................................... 5 Today’s challenges .............................................................................. 8 The future of energy .......................................................................... 11 A solution: Decentralisation ............................................................... 14 Why focus on communities? .............................................................. 15 What can we learn from other countries? ........................................ 20 A platform for success ...................................................................... 24 How will it work? ............................................................................... 25 Government support ......................................................................... 26 Appendix: The UK Government’s community energy strategy ....... 27 Bibliography ....................................................................................... 29 2 Letter from the CEO All industries evolve. If they don’t, they die out or are supplanted by something different. Evolution can take many forms - value for money, customer service, product innovation, operational efficiency. But one way or another, change means survival and growth.
    [Show full text]
  • Magnox Electric Plc's Strategy for Decommissioning Its Nuclear
    A review by HM Nuclear Installations Inspectorate Magnox Electric plc’s strategy for decommissioning its nuclear licensed sites A review by HM Nuclear Installations Inspectorate Magnox Electric plc’s strategy for decommissioning its nuclear licensed sites Published by the Health and Safety Executive February 2002 Further copies are available from: Health and Safety Executive Nuclear Safety Directorate Information Centre Room 004 St Peter’s House Balliol Road, Bootle Merseyside L20 3LZ Tel: 0151 951 4103 Fax: 0151 951 4004 E-mail: [email protected] Available on the Internet from: http://www.open.gov.uk/hse/nsd ii FOREWORD This report sets out the findings of a review by the Health and Safety Executive’s Nuclear Installation Inspectorate, in consultation with the environment agencies, of the Magnox Electric plc (Magnox Electric) decommissioning and waste management strategies for its nuclear licensed sites. The review was undertaken in accordance with the 1995 White Paper “Review of Radioactive Waste Management Policy: Final Conclusions”, Cm 2919, which stated that the Government would ask all nuclear operators to draw up strategies for the decommissioning of their redundant plant and that the Health and Safety Executive (HSE) would review these strategies on a quinquennial basis in consultation with the environment agencies. The Magnox Electric strategy upon which this review is based was prepared subsequent to the merger of Magnox Electric with British Nuclear Fuels plc (BNFL) but whilst it still remained a separate nuclear site licensee under the Nuclear Installations Act 1965 (as amended). This report therefore considers Magnox Electric’s decommissioning and waste management strategies as of April 2000 for its nuclear licensed sites at: Berkeley, Bradwell, Dungeness A, Hinkley Point A, Hunterston A, Oldbury, Sizewell A, Trawsfynydd and Wylfa; and at the Berkeley Centre; and for the financial liabilities for waste and decommissioning on other nuclear licensed sites (e.g.
    [Show full text]
  • Endless Trouble: Britain's Thermal Oxide Reprocessing Plant
    Endless Trouble Britain’s Thermal Oxide Reprocessing Plant (THORP) Martin Forwood, Gordon MacKerron and William Walker Research Report No. 19 International Panel on Fissile Materials Endless Trouble: Britain’s Thermal Oxide Reprocessing Plant (THORP) © 2019 International Panel on Fissile Materials This work is licensed under the Creative Commons Attribution-Noncommercial License To view a copy of this license, visit ww.creativecommons.org/licenses/by-nc/3.0 On the cover: the world map shows in highlight the United Kingdom, site of THORP Dedication For Martin Forwood (1940–2019) Distinguished colleague and dear friend Table of Contents About the IPFM 1 Introduction 2 THORP: An Operational History 4 THORP: A Political History 11 THORP: A Chronology 1974 to 2018 21 Endnotes 26 About the authors 29 About the IPFM The International Panel on Fissile Materials (IPFM) was founded in January 2006 and is an independent group of arms control and nonproliferation experts from both nuclear- weapon and non-nuclear-weapon states. The mission of the IPFM is to analyze the technical basis for practical and achievable pol- icy initiatives to secure, consolidate, and reduce stockpiles of highly enriched uranium and plutonium. These fissile materials are the key ingredients in nuclear weapons, and their control is critical to achieving nuclear disarmament, to halting the proliferation of nuclear weapons, and to ensuring that terrorists do not acquire nuclear weapons. Both military and civilian stocks of fissile materials have to be addressed. The nuclear- weapon states still have enough fissile materials in their weapon stockpiles for tens of thousands of nuclear weapons. On the civilian side, enough plutonium has been sepa- rated to make a similarly large number of weapons.
    [Show full text]