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市場調查報告書

全球核能發電產業

Global Nuclear Power Industry 2016

出版商 Aruvian's R'search 商品編碼 146136
出版日期 內容資訊 英文 580 Pages
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全球核能發電產業 Global Nuclear Power Industry 2016
出版日期: 2016年09月16日 內容資訊: 英文 580 Pages
簡介

本報告提供全球核能發電產業調查分析,概要,統計,價格趨勢,產業趨勢,發電能力,波特的五力分析,加上經濟狀況,氣候變動,課題,管理方案,各地區的市場分析等系統性資訊。

A. 摘要整理

B. 全球核能發電產業分析

  • 產業概要
  • 產業統計
  • 產業區分
  • 核子反應爐的性能提高
  • 產業趨勢
  • 核能發電能力的擴大可能性
  • 新的核能發電能力的追加
  • 核能發電相關世間的支持

C. 全球核能發電產業:波特的五力分析

  • 簡介
  • 買主談判力
  • 供應商談判力
  • 同業者間的競爭
  • 新加入廠商的威脅
  • 替代品的威脅

D. 經濟狀況分析

  • 資本成本
  • 運用成本
  • 系統成本
  • 外部成本
  • 經濟性:核能發電 vs. 其他發電
  • 未來的成本競爭力
  • 投資獎金

E. 地球的氣候變動和核能發電

F. 核能發電所面臨的課題

  • 大氣污染
  • 健康的影響
  • 財政的課題
  • 核能安全性
  • 核的擴散
  • 法規上的障礙
  • 水質污染
  • 其他的課題

G. 管理方案

  • 尖端核燃料循環研究開發構想 (AFCI)
  • 第4代核能系統構想
  • 國際核能研究倡議
  • 核能發電 2010年
  • 核能氫倡議
  • 美國的大氣淨化法
  • 美國的國家能源政策

H. 核能發電及其他電源比較

I. 核能發電的未來

J. 全球核能發電產業分析

  • 阿根廷
  • 巴西
  • 加拿大
  • 中國
  • 捷克
  • 法國
  • 德國
  • 印度
  • 伊朗
  • 義大利
  • 日本
  • 哈薩克
  • 立陶宛
  • 墨西哥
  • 北韓
  • 巴基斯坦
  • 羅馬尼亞
  • 俄羅斯
  • 南非
  • 韓國
  • 台灣
  • 烏克蘭
  • 英國
  • 美國

K. 主要企業:企業、核能發電設施

  • Alstom SA
  • Ameren Corporation
  • American Electric Power Company
  • Areva SA
  • Bharat Heavy Electrical Limited
  • Bruce Power
  • Cameco Corporation
  • Centrais Eletricas Brasileiras SA
  • 中部電力
  • Comision Federal de Electricidad
  • Dongfang Electric Corporation
  • Duke Energy Corporation
  • E.ON SE
  • EDF Electricite de France SA
  • Electrabel
  • Enbw Energie Baden Wuerttemberg AG
  • Endesa SA
  • Entergy Corporation
  • Eskom Holdings
  • Exelon Corporation
  • 日立製作所
  • General Electric
  • Iberdrola SA
  • Korea Electric Power Corporation
  • 三菱重工業
  • Nuclear Power Corporation of India Ltd
  • Ontario Power Generation (OPG)
  • RWE AG
  • Siemens AG
  • 東京電力集團
  • 東芝
  • Vattenfall AB
  • China National Nuclear Corporation (CNNC)
  • Energoatom
  • Nucleoelectrica Argentina S.A.
  • Paks Nuclear Power Plant Company
  • Societatea Nationala Nuclearelectrica SA
  • Westinghouse Electric Company, LLC

L. 附錄

M. 詞彙表

圖表

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目錄

With the Fukushima accident in 2011, the global nuclear industry has come under the spotlight as governments worldwide discuss the pros and cons of nuclear power. Regardless of the safety concerns of nuclear power, there is no doubt that nuclear power is here to stay. While many countries have put in motion plans to phase out nuclear power, there are many who are actively boosting the growth of nuclear power.

With the recent spate of nuclear accidents, the global nuclear power industry has seen deterioration over recent years, but nevertheless, the industry is expected to expand and post a strong growth rate in the years to 2020. There are over 400 civil nuclear power reactors in operation around the world today, with the US accounting for nearly one third of the world's nuclear electricity.

Aruvian Research analyzes the Global Nuclear Power Industry in this in-depth research report. The report begins with an analysis of the industry statistics. We analyze the global nuclear power industry through an industry overview, industry statistics from 2011-2015, industry segmentation, amongst others. We also look at price trends for nuclear power, industry trends, a look at the expansion of nuclear power capacity, addition of new capacity and the public acceptance of nuclear power. A Porter's Five Forces Strategy analysis of the Global Nuclear Power Industry is also carried out.

We analyze the economics of nuclear power through capital costs, operation costs, system costs, external costs, economics of nuclear power versus other forms of electricity generation and the cost competitiveness of nuclear power in the future. Investment incentives for nuclear power are also looked at.

Climate change is an integral part of the energy industry today and we look at the global climate change and impact of nuclear power on this. Furthermore, we also look at the challenges and barriers facing nuclear power.

Global regulatory initiatives that govern the nuclear power industry such as the U.S. Clean Air Act, Nuclear Power 2010, International Nuclear Energy Research Initiative and others are analyzed in the report.

Outlook for the global nuclear power industry to the year 2020 is included in the year, as well as a comparison of nuclear power to other power resources is included in the analysis of the Global Nuclear Power Industry.

Following this, we move on to the analysis of the key nuclear power markets worldwide. We analyze many nuclear markets worldwide including Japan, China, India, the US, Ukraine, Russia, etc. For each market we analyze the industry through an overview, nuclear capacity, fuel cycle details, regulatory framework governing the industry, research and development efforts, nuclear waste management and nuclear non-proliferation.

Argentina, Brazil, Canada, China, Czech Republic, France, Germany, India, Iran, Italy, Japan, Kazakhstan, Lithuania, Mexico, North Korea, Pakistan, Romania, Russia, South Africa, South Korea, Taiwan, Ukraine, the United Kingdom and the United States.

No industry analysis is complete without a look at the major industry players and we analyze the leading players in the Global Nuclear Power Industry through a business profile, financial analysis and a SWOT analysis. The analysis looks at both nuclear power companies as well as nuclear power utilities.

Table of Contents

A. Executive Summary

B. Analyzing the Global Nuclear Power Industry

  • B.1 Industry Overview
  • B.2 Industry Statistics
  • B.3 Industry Segmentation
  • B.4 Improving the Performance of Nuclear Reactors
  • B.5 Industry Trends
  • B.6 Exploring the Possibility of Expansion of Nuclear Power Capacity
  • B.7 Addition of New Nuclear Power Capacity
    • B.7.1 Increased Nuclear Capacity
    • B.7.2 New Nuclear Plant Construction
    • B.7.3 Plant Life Extension and Decommissions
  • B.8 Public Acceptance of Nuclear Power

C. Global Nuclear Power Industry: Porter's Five Forces Strategy Analysis

  • C.1 Introduction
  • C.2 Bargaining Power of Buyers
  • C.3 Bargaining Power of Suppliers
  • C.4 Competitive Rivalry in the Industry
  • C.5 Threat of New Entrants
  • C.6 Threat of Substitutes

D. Analyzing the Economics

  • D.1 Capital Cost
  • D.2 Operation Costs
  • D.3 System Costs
  • D.4 External Costs
  • D.5 Economics of Nuclear Power versus Other Forms of Electricity Generation
  • D.6 Cost Competitiveness in the Future
  • D.7 Investment Incentives

E. Global Climate Change & Nuclear Power

F. Challenges Facing Nuclear Power

  • F.1 Air Pollution
  • F.2 Health Effects
  • F.3 Financial Challenges
  • F.4 Nuclear Safety
  • F.5 Nuclear Proliferation
  • F.6 Regulatory Barriers
  • F.7 Water Pollution
  • F.8 Other Challenges

G. Regulatory Initiatives

  • G.1 Advanced Fuel Cycle Initiative
  • G.2 Generation IV Nuclear Energy Systems Initiative
  • G.3 International Nuclear Energy Research Initiative
  • G.4 Nuclear Power 2010
  • G.5 Nuclear Hydrogen Initiative
  • G.6 U.S. Clean Air Act
  • G.7 National Energy Policy of the U.S.
    • G.7.1 Nuclear Energy under Obama
      • G.7.1.1 Obama's Approach
      • G.7.1.2 Loan for Nuclear
      • G.7.1.3 Nuclear Policy for the World
      • G.7.1.4 Impact
      • G.7.1.5 About Nuclear Posture Review
      • G.7.1.6 China
      • G.7.1.7 Russia

H. Comparing Nuclear Power to Other Power Sources

I. Future of Nuclear Power

J. Analyzing the Global Nuclear Power Industry

  • J.1 Argentina
    • J.1.1 Industry Overview
    • J.1.2 Industry Statistics
    • J.1.4 Nuclear Capacity
    • J.1.5 Fuel Cycle
    • J.1.6 Regulatory Framework
    • J.1.7 Research & Development
    • J.1.8 Managing Nuclear Waste
    • J.1.9 Nuclear Non Proliferation
  • J.2 Brazil
    • J.2.1 Industry Overview
    • J.2.2 Nuclear Capacity
    • J.2.3 Regulatory Framework
    • J.2.4 Research & Development
    • J.2.5 Managing Nuclear Waste
    • J.2.6 Nuclear Non Proliferation
  • J.3 Canada
    • J.3.1 Industry Overview
    • J.3.2 Nuclear Capacity
    • J.3.3 Decommissioning
    • J.3.4 Fuel Cycle
    • J.3.5 Research & Development
    • J.3.6 Nuclear Non Proliferation
  • J.4 China
    • J.4.1 Industry Overview
    • J.4.2 Nuclear Capacity
    • J.4.3 Fuel Cycle
    • J.4.4 Regulatory Framework
    • J.4.5 Managing Nuclear Waste
  • J.5 Czech Republic
    • J.5.1 Industry Overview
    • J.5.2 Nuclear Capacity
    • J.5.3 Fuel Cycle
    • J.5.4 Regulatory Framework
    • J.5.5 Research & Development
    • J.5.6 Managing Nuclear Waste
    • J.5.7 Nuclear Non Proliferation
  • J.6 France
    • J.6.1 Industry Overview
    • J.6.2 Nuclear Capacity
    • J.6.3 Decommissioning
    • J.6.4 Fuel Cycle
    • J.6.5 Regulatory Framework
    • J.6.6 Research & Development
    • J.6.7 Managing Nuclear Waste
    • J.6.8 Nuclear Non Proliferation
  • J.7 Germany
    • J.7.1 Industry Overview
    • J.7.2 Nuclear Capacity
    • J.7.3 Decommissioning
    • J.7.4 Fuel Cycle
    • J.7.5 Regulatory Framework
    • J.7.6 Research & Development
    • J.7.7 Managing Nuclear Waste
    • J.7.8 Public Opinion
    • J.7.9 Nuclear Non Proliferation
  • J.8 India
    • J.8.1 Industry Overview
    • J.8.2 Nuclear Capacity
    • J.8.3 Nuclear Energy Parks
    • J.8.4 Fuel Cycle
    • J.8.5 Regulatory Framework
    • J.8.6 Research & Development
    • J.8.7 Managing Nuclear Waste
    • J.8.8 Nuclear Non Proliferation
  • J.9 Iran
    • J.9.1 Industry Overview
    • J.9.2 Nuclear Capacity
    • J.9.3 Fuel Cycle
    • J.9.4 Regulatory Framework
    • J.9.5 Research & Development
    • J.9.6 Nuclear Non Proliferation
  • J.10 Italy
    • J.10.1 Industry Overview
    • J.10.2 Nuclear Capacity
    • J.10.3 Fuel Cycle
    • J.10.4 Regulatory Framework
    • J.10.5 Research & Development
    • J.10.6 Managing Nuclear Waste
    • J.10.7 Public Opinion
    • J.10.8 Nuclear Non Proliferation
  • J.11 Japan
    • J.11.1 Industry Overview
    • J.11.2 Industry Statistics
    • J.11.3 Impact of Fukushima Accident
    • J.11.4 Nuclear Capacity
    • J.11.5 Decommissioning
    • J.11.6 Fuel Cycle
    • J.11.7 Regulatory Framework
    • J.11.8 Research & Development
    • J.11.9 Managing Nuclear Waste
    • J.11.10 Public Opinion
    • J.11.11 Nuclear Non Proliferation
  • J.12 Kazakhstan
    • J.12.1 Industry Overview
    • J.12.2 Fuel Cycle
    • J.12.3 Regulatory Framework
    • J.12.4 Research & Development
    • J.12.5 Managing Nuclear Waste
    • J.12.6 Nuclear Non Proliferation
  • J.13 Lithuania
    • J.13.1 Industry Overview
    • J.13.2 Nuclear Capacity
    • J.13.3 Decommissioning
    • J.13.4 Regulatory Framework
    • J.13.5 Managing Nuclear Waste
    • J.13.6 Public Opinion
    • J.13.7 Nuclear Non Proliferation
  • J.14 Mexico
    • J.14.1 Industry Overview
    • J.14.2 Nuclear Capacity
    • J.14.3 Fuel Cycle
    • J.14.4 Regulatory Framework
    • J.14.5 Research & Development
    • J.14.6 Managing Nuclear Waste
    • J.14.7 Nuclear Non Proliferation
  • J.15 North Korea
  • J.16 Pakistan
    • J.16.1 Industry Overview
    • J.16.2 Nuclear Capacity
    • J.16.3 Fuel Cycle
    • J.16.4 Regulatory Framework
    • J.16.5 Research & Development
    • J.16.6 Managing Nuclear Waste
    • J.16.7 Nuclear Non Proliferation
  • J.17 Romania
    • J.17.1 Industry Overview
    • J.17.2 Nuclear Capacity
    • J.17.3 Fuel Cycle
    • J.17.4 Regulatory Framework
    • J.17.5 Research & Development
    • J.17.6 Managing Nuclear Waste
    • J.17.7 Nuclear Non Proliferation
  • J.18 Russia
    • J.18.1 Industry Overview
    • J.18.2 Nuclear Capacity
    • J.18.3 Decommissioning
    • J.18.4 Fuel Cycle
    • J.18.5 Regulatory Framework
    • J.18.6 Research & Development
    • J.18.7 Managing Nuclear Waste
    • J.18.8 Public Opinion
    • J.18.9 Nuclear Non Proliferation
  • J.19 South Africa
    • J.19.1 Industry Overview
    • J.19.2 Nuclear Capacity
    • J.19.3 Fuel Cycle
    • J.19.4 Regulatory Framework
    • J.19.5 Research & Development
    • J.19.6 Managing Nuclear Waste
    • J.19.7 Nuclear Non Proliferation
  • J.20 South Korea
  • J.21.1 Industry Overview
    • J.21.2 Nuclear Capacity
    • J.21.3 Fuel Cycle
    • J.21.4 Regulatory Framework
    • J.21.5 Research & Development
    • J.21.6 Managing Nuclear Waste
    • J.21.7 Nuclear Non Proliferation
  • J.22 Taiwan
    • J.22.1 Industry Overview
    • J.22.2 Fuel Cycle
    • J.22.3 Research & Development
    • J.22.4 Nuclear Non Proliferation
  • J.23 Ukraine
    • J.23.1 Industry Overview
    • J.23.2 Nuclear Capacity
    • J.23.3 Decommissioning
    • J.23.4 Fuel Cycle
    • J.23.5 Research & Development
    • J.23.6 Managing Nuclear Waste
    • J.23.7 Nuclear Non Proliferation
  • J.24 United Kingdom
    • J.24.1 Industry Overview
    • J.24.2 Nuclear Capacity
    • J.24.3 Fuel Cycle
    • J.24.4 Regulatory Framework
    • J.24.5 Research & Development
    • J.24.6 Managing Nuclear Waste
    • J.24.7 Nuclear Non Proliferation
  • J.25 United States
    • J.26.1 Industry Overview
    • J.26.2 Nuclear Capacity
    • J.26.3 Decommissioning
    • J.26.4 Managing Nuclear Waste

K. Major Players - Companies & Nuclear Power Utilities

  • K.1 Alstom SA
    • K.1.1 Business Profile
    • K.1.2 Financial Analysis
    • K.1.3 SWOT Analysis
  • K.2 Ameren Corporation
    • K.2.1 Business Profile
    • K.2.2 Financial Analysis
    • K.2.3 SWOT Analysis
  • K.3 American Electric Power Company
    • K.3.1 Business Profile
    • K.3.2 Financial Analysis
    • K.3.3 SWOT Analysis
  • K.4 Areva SA
    • K.4.1 Business Profile
    • K.4.2 Financial Analysis
    • K.4.3 SWOT Analysis
  • K.5 Bharat Heavy Electrical Limited
    • K.5.1 Business Profile
    • K.5.2 Financial Analysis
    • K.5.3 SWOT Analysis
  • K.6 Bruce Power
    • K.6.1 Business Profile
    • K.6.2 Financial Analysis
    • K.6.3 SWOT Analysis
  • K.7 Cameco Corporation
    • K.7.1 Business Profile
    • K.7.2 Financial Analysis
    • K.7.3 SWOT Analysis
  • K.8 Centrais Eletricas Brasileiras SA
    • K.8.1 Business Profile
    • K.8.2 Financial Analysis
    • K.8.3 SWOT Analysis
  • K.9 Chubu Electric Power Company
    • K.9.1 Business Profile
    • K.9.2 Financial Analysis
    • K.9.3 SWOT Analysis
  • K.10 Comision Federal de Electricidad
    • K.10.1 Business Profile
    • K.10.2 Financial Analysis
    • K.10.3 SWOT Analysis
  • K.11 Dongfang Electric Corporation
    • K.11.1 Business Profile
    • K.11.2 Financial Analysis
    • K.11.3 SWOT Analysis
  • K.12 Duke Energy Corporation
    • K.12.1 Business Profile
    • K.12.2 Financial Analysis
    • K.12.3 SWOT Analysis
  • K.13 E.ON SE
    • K.13.1 Business Profile
    • K.13.2 Financial Analysis
    • K.13.3 SWOT Analysis
  • K.14 EDF Electricité de France SA
    • K.14.1 Business Profile
    • K.14.2 Financial Analysis
    • K.14.3 SWOT Analysis
  • K.15 Electrabel
    • K.15.1 Business Profile
    • K.15.2 Financial Analysis
    • K.15.3 SWOT Analysis
  • K.16 Enbw Energie Baden Wuerttemberg AG
    • K.16.1 Business Profile
    • K.16.2 Financial Analysis
    • K.16.3 SWOT Analysis
  • K.17 Endesa SA
    • K.17.1 Business Profile
    • K.17.2 Financial Analysis
    • K.17.3 SWOT Analysis
  • K.18 Entergy Corporation
    • K.18.1 Business Profile
    • K.18.2 Financial Analysis
    • K.18.3 SWOT Analysis
  • K.19 Eskom Holdings
    • K.19.1 Business Profile
    • K.19.2 Financial Analysis
    • K.19.3 SWOT Analysis
  • K.20 Exelon Corporation
    • K.20.1 Business Profile
    • K.20.2 Financial Analysis
    • K.20.3 SWOT Analysis
  • K.21 Hitachi
    • K.21.1 Business Profile
    • K.21.2 Financial Analysis
    • K.21.3 SWOT Analysis
  • K.22 General Electric
    • K.22.1 Business Profile
    • K.22.2 Financial Analysis
    • K.22.3 SWOT Analysis
  • K.23 Iberdrola SA
    • K.23.1 Business Profile
    • K.23.2 Financial Analysis
    • K.23.3 SWOT Analysis
  • K.24 Korea Electric Power Corporation
    • K.24.1 Business Profile
    • K.24.2 Financial Analysis
    • K.24.3 SWOT Analysis
  • K.25 Mitsubishi Heavy Industries Ltd
    • K.25.1 Business Profile
    • K.25.2 Financial Analysis
    • K.25.3 SWOT Analysis
  • K.26 Nuclear Power Corporation of India Ltd
    • K.26.1 Business Profile
    • K.26.2 Financial Analysis
    • K.26.3 SWOT Analysis
  • K.27 Ontario Power Generation (OPG)
    • K.27.1 Business Profile
    • K.27.2 Financial Analysis
    • K.27.3 SWOT Analysis
  • K.28 RWE AG
    • K.28.1 Business Profile
    • K.28.2 Financial Analysis
    • K.28.3 SWOT Analysis
  • K.29 Siemens AG
    • K.29.1 Business Profile
    • K.29.2 Financial Analysis
    • K.29.3 SWOT Analysis
  • K.30 Tokyo Electric Power Company Holdings
    • K.30.1 Business Profile
    • K.30.2 Financial Analysis
    • K.30.3 SWOT Analysis
  • K.31 Toshiba Corporation
    • K.31.1 Business Profile
    • K.31.2 Financial Analysis
    • K.31.3 SWOT Analysis
  • K.32 Vattenfall AB
    • K.32.1 Business Profile
    • K.32.2 Financial Analysis
    • K.32.3 SWOT Analysis
  • K.33 China National Nuclear Corporation (CNNC)
  • K.34 Energoatom
  • K.35 Nucleoelectrica Argentina S.A.
  • K.36 Paks Nuclear Power Plant Company
  • K.37 Societatea Nationala Nuclearelectrica SA
  • K.38 Westinghouse Electric Company, LLC

L. Appendix

  • L.1 Nuclear Trade & Industry Organizations
  • L.2 Regulation & Regulators for the Nuclear Industry
  • L.3 Worldwide Nuclear Research Centers
  • L.4 Non Proliferation & Safeguards Organizations
  • L.5 Figures & Tables

M. Glossary of Terms

List of Figures

  • Figure 1: Nuclear Electricity Production and Share of Total Electricity Production (in TWh), 1970-2015
  • Figure 2: Share of the Global Nuclear Power Industry by Regions (%), 2015
  • Figure 3: Global Electricity Production by Power Sources (%), 2012
  • Figure 4: Fuel Used for Electricity Generation, 2012
  • Figure 5: Nuclear Generation by Country, 2015
  • Figure 6: Porter's Five Forces Analysis of the Global Nuclear Power Industry
  • Figure 7: Bargaining Power of Buyers in the Global Nuclear Power Industry
  • Figure 8: Bargaining Power of Suppliers in the Global Nuclear Power Industry
  • Figure 9: Competitive Rivalry in the Global Nuclear Power Industry
  • Figure 10: Threat of New Entrants in the Global Nuclear Power Industry
  • Figure 11: Threat of Substitutes in the Global Nuclear Power Industry
  • Figure 12: Investment Cost over Time by Sit (in USD per kW), 2013 Prices
  • Figure 13: Overnight Capital Cost Range by Region (in USD per kW), 2013 Prices
  • Figure 14: Comparative LCOEs and System Costs in France, South Korea, UK and US, 2012 & 2014
  • Figure 15: Electricity Production Costs in the US, 1995-2012
  • Figure 16: Impact of Fuel Costs on Electricity Generation Costs
  • Figure 17: Effect of Uranium Price on Fuel Cost
  • Figure 18: Forecast of the Global Nuclear Energy Industry (in USD Billion), 2015-2020
  • Figure 19: Forecast for the Global Nuclear Energy Industry (in Million GWh), 2015-2020
  • Figure 20: Nuclear Reactors in China
  • Figure 21: Nuclear Power Plans of China Guangdong Nuclear Power Group to 2020
  • Figure 22: Nuclear Plants under Construction in China
  • Figure 23: Expected Nuclear Power Capacity in India, 1969-2017
  • Figure 24: Operating and Under Construction Nuclear Power Plants in India
  • Figure 25: Planned Nuclear Power Plants in India
  • Figure 26: Structure of the Indian Nuclear Power Industry
  • Figure 27: Planned/Proposed Nuclear Power Reactors in Japan
  • Figure 28: New Nuclear Capacity being Planned and Retirements of Nuclear Reactors in Russia up to 2035
  • Figure 29: Nuclear Power Load Factors
  • Figure 30: Nuclear Power Plants in the US
  • Figure 31: Pressurized Water Reactor
  • Figure 32: Pressurized Water Reactor Vessel
  • Figure 33: Boiling Water Reactor
  • Figure 34: Advanced Liquid Metal Reactor
  • Figure 35: Radioisotope Thermoelectric Generator of Cassini Probe
  • Figure 36: Process depicting Nuclear Fuel Cycle
  • Figure 37: Thermal Conductivity of Zirconium Metal & Uranium Dioxide as a Function of Temperature
  • Figure 38: A Control Rod Assembly
  • Figure 39: A Steel Pressure Vessel
  • Figure 40: A Siemens Steam Turbine with Open Case
  • Figure 41: Sources of Nuclear Waste
  • Figure 42: Competitors of Nuclear Power

List of Tables

  • Table 1: Global Nuclear Power Industry by Regions (in USD Billion & %), 2015
  • Table 2: Power Reactors under Construction
  • Table 3: Cost of Procuring 1Kg of Uranium as UO2 Reactor Fuel as of July 2015
  • Table 4: Projected Nuclear LCOE Costs for Plants Built 2015-2020, $/MWh
  • Table 5: OECD Electricity Generating Cost Projections for 2010 on - 5% Discount Rate, c/kWh
  • Table 6: OECD Electricity Generating Cost Projections for Year 2010 on - 10% Discount Rate, c/kWh
  • Table 7: Economics of Fossil-Fired Electricity Generation
  • Table 8: Forecast of the Global Nuclear Energy Industry (in USD Billion), 2015-2020
  • Table 9: Forecast for the Global Nuclear Energy Industry (in Million GWh), 2015-2020
  • Table 10: Operating Nuclear Power Reactors in Argentina
  • Table 11: Nuclear Power Reactors Planned/Under Construction in Argentina
  • Table 12: Nuclear Power Reactors Operating in Brazil
  • Table 13: Nuclear Power Reactors under Construction/Proposed in Brazil
  • Table 14: Operating Nuclear Power Reactors in Canada
  • Table 15: Planned/Proposed Nuclear Power Reactors in Canada
  • Table 16: Operating Nuclear Reactors in China
  • Table 17 : Nuclear Reactors under Construction & Planned in China
  • Table 18: Proposed Nuclear Power Plants in China
  • Table 19: Power Reactors in Czech Republic
  • Table 20: Planned/Proposed Power Reactors in Czech Republic
  • Table 21: Nuclear Power Reactors in France
  • Table 22: Nuclear Power Reactors Under Construction/Planned in France
  • Table 23: Decommissioned Nuclear Power Reactors in France
  • Table 24: Nuclear Power Units in Germany
  • Table 25: Decommissioned Nuclear Power Reactors in Germany
  • Table 26: Operating Nuclear Power Reactors in India
  • Table 27: Nuclear Power Reactors Under Construction in India
  • Table 28: Nuclear Power Reactors Planned in India
  • Table 29: Nuclear Power Reactors Proposed in India
  • Table 30: Nuclear Power Reactors in Iran
  • Table 31: Nuclear Power Reactors Planned/Proposed in Iran
  • Table 32: Former Nuclear Power Reactors of Italy
  • Table 33: Operational Nuclear Power Reactors in Japan
  • Table 34: Nuclear Power Reactors under Construction in Japan
  • Table 35: Planned/Proposed Nuclear Power Reactors in Japan
  • Table 36: Nuclear Power Reactors Shutdown in Lithuania
  • Table 37: Planned Nuclear Power Reactors in Lithuania
  • Table 38: Nuclear Power Reactors in Operation in Mexico
  • Table 39: Operating Nuclear Power Reactors in Pakistan
  • Table 40: Nuclear Power Reactors under Construction/Planned in Pakistan
  • Table 41: Operating Nuclear Power Reactors in Romania
  • Table 42: Planned Nuclear Power Reactors in Romania
  • Table 43: Nuclear Power Reactors in Operation in Russia
  • Table 44: Major Power Reactors under Construction, Planned/Proposed in Russia
  • Table 45: Nuclear Power Reactors Planned/Officially Proposed
  • Table 46: Nuclear Power Reactors Proposed in Russia with Status Uncertain
  • Table 47: Shutdown Civil Nuclear Power Reactors in Russia
  • Table 48: Operating Nuclear Power Reactors in South Africa
  • Table 49: Proposed Nuclear Power Reactors in South Africa
  • Table 50: Nuclear Power Reactors in Operation in South Korea
  • Table 51: Nuclear Power Reactors Under Construction/Planned in South Korea
  • Table 52: Nuclear Power Reactors in Taiwan
  • Table 53: Nuclear Power Reactors in Operation in Ukraine
  • Table 54: Nuclear Power Reactor Construction, Planned/Proposed in Ukraine
  • Table 55: Nuclear Power Reactors Operating in the UK
  • Table 56: Nuclear Power Reactors Planned/Proposed in the UK
  • Table 57: Nuclear Power Reactors under Construction in the US
  • Table 58: Nuclear Power Reactors Planned/Proposed in the US
  • Table 59: Estimates of Total Electricity Generation and the Contribution of Nuclear Power
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