Japan's Revival of Nuclear Energy Post Fukushima

Nico Godsick
March 11, 2024

Submitted as coursework for PH241, Stanford University, Winter 2024

Introduction

Fig. 1: Japan's nuclear electricity production recovery post-Fukushima. [4,5] (Image Source: N. Godsick)

Japan's journey with nuclear energy began in the 1950s, fueled by the desire for energy security and economic growth. Over the decades, nuclear power became a cornerstone of Japan's energy policy, leading to the development of numerous reactors across the country. This reliance on nuclear energy was dramatically challenged by the Fukushima Daiichi nuclear disaster in March 2011, caused by a massive earthquake and subsequent tsunami. The incident, marked by severe nuclear meltdowns and release of radioactive materials, led to a nationwide shutdown of nuclear reactors and a reevaluation of Japan's nuclear energy policies. [1] The Fukushima disaster not only prompted rigorous safety reviews and regulatory reforms but also ignited intense public debate on the future role of nuclear power in Japan, leading to a significant shift in the country's approach to nuclear energy and broader energy strategy. [2]

Causes and Consequences on Fukushima

The Fukushima Daiichi nuclear disaster on March 11, 2011, was precipitated by a magnitude 9.0 earthquake and a subsequent tsunami, both of which caused catastrophic damage. The earthquake itself did not inflict severe damage on the reactors, but it did cause the loss of all external power sources. The emergency diesel generators initially provided power but were soon disabled by the tsunami waves, leading to a station blackout. The reactors, unable to cool down due to the loss of power, began to overheat. Despite attempts to cool them with seawater, the situation worsened. This led to meltdowns in three of the six reactors. The environmental, economic, and social impacts were profound. Radioactive material was released, causing widespread contamination. This revelation had significant implications for environmental remediation strategies. Public opinion and governmental policies on nuclear energy shifted dramatically post-Fukushima. The disaster catalyzed a reevaluation of nuclear safety and emergency preparedness, especially in seismically active areas. This led to stricter safety protocols and a renewed focus on alternative energy sources. [3]

Japan's nuclear electricity production took a drastic dip following the disaster. In 2010 the country was producing 280.25 terawatt-hours (TW-h) of electricity per year. This accounted for 29.2% of the nation's output. In 2015, just 5 years later (and 4 years following the disaster) these numbers decreased to 4.35 TW-h, which amounted to and 0.44%. [4]

Policy and Regulatory Changes Post-Fukushima

After the Fukushima Daiichi nuclear disaster in 2011, Japan's nuclear energy policy and regulatory landscape underwent significant changes. The immediate aftermath of the disaster led to a drastic reduction in nuclear power generation in Japan, with widespread public skepticism and apprehension about the safety of nuclear energy. This sentiment was echoed in the policies that followed. The Fukushima disaster prompted Japan to introduce new safety standards and establish new regulatory bodies to oversee the nuclear energy sector. These changes were part of a broader effort to rebuild confidence in nuclear power, both nationally and internationally. This approach was combined with ongoing innovations in reactor design and performance, including the development of small modular reactors (SMRs) which are generally simpler and rely more extensively on inherent and passive safety features. [2]

Japan's Nuclear Energy Compared to the World

Japan's nuclear energy policy, especially after the Fukushima Daiichi disaster, stands in contrast to the approaches taken by other countries (see Fig. 1). While nations like Germany decided to phase out nuclear power entirely by 2022, Japan has pursued a more cautious path, focusing on enhancing safety standards and gradually reintroducing nuclear power. The strategy involves deploying new technologies such as low-carbon hydrogen, advanced nuclear reactors, and carbon recycling, highlighting Japan's commitment to creating a balance between economic growth and environmental protection. However, the implementation of this nuclear policy faces challenges, including community agreements for plant restarts, legal hurdles, and high costs associated with new reactor technologies, as well as public skepticism and unresolved issues from the Fukushima disaster.

Conclusion

In conclusion, Japan's nuclear energy landscape has undergone a profound transformation since the Fukushima disaster in 2011. The incident not only reshaped public opinion and policy regarding nuclear power but also catalyzed a shift towards enhanced safety measures and a greater emphasis on renewable energy. As Japan continues to navigate the challenges of balancing energy security, environmental sustainability, and public safety, its approach serves as a significant case study in the global discourse on the role and future of nuclear energy.

© Nico Godsick. The author warrants that the work is the author's own and that Stanford University provided no input other than typesetting and referencing guidelines. The author grants permission to copy, distribute and display this work in unaltered form, with attribution to the author, for noncommercial purposes only. All other rights, including commercial rights, are reserved to the author.

References

[1] K. Hirose, "2011 Fukushima Dai-ichi Nuclear Power Plant Accident: Summary of Regional Radioactive Deposition Monitoring Results," J. Environ. Radioact. 111, 13 (2012).

[2] F. Koppenborg, Japan's Nuclear Disaster and the Politics of Safety Governance (Cornell University Press, 2023) p. 2

[3] S. Wright, Fukushima Daiichi: Causes and Consequences (Nova Science Publishers, 2017).

[4] "Nuclear Power Reactors in the World, 2021 Edition," International Atomic Energy Agency, IAEA-RDS-2/41, July 2021.

[5] "BP Statistical Review of World Energy 2022," British Petroleum, June 2022.