24 Items

A photo of electrolysis in action. (Flickr: ca_heckler)

Flickr: ca_heckler / CC by-nc-nd 2.0

Report

Geopolitical and Market Implications of Renewable Hydrogen: New Dependencies in a Low-Carbon Energy World

| March 2020

To accelerate the global transition to a low-carbon economy, all energy systems and sectors must be actively decarbonized. While hydrogen has been a staple in the energy and chemical industries for decades, renewable hydrogen is drawing increased attention today as a versatile and sustainable energy carrier with the potential to play an important piece in the carbon-free energy puzzle. Countries around the world are piloting new projects and policies, yet adopting hydrogen at scale will require innovating along the value chains; scaling technologies while significantly reducing costs; deploying enabling infrastructure; and defining appropriate national and international policies and market structures.

What are the general principles of how renewable hydrogen may reshape the structure of global energy markets? What are the likely geopolitical consequences such changes would cause? A deeper understanding of these nascent dynamics will allow policy makers and corporate investors to better navigate the challenges and maximize the opportunities that decarbonization will bring, without falling into the inefficient behaviors of the past.

A member of the Czech Army takes part in an anti-terrorism drill at the Temelin nuclear power plant near the town of Tyn nad Vltavou, Czech Republic, April 11, 2017.

REUTERS/David W. Cerny

Report - Belfer Center for Science and International Affairs, Harvard Kennedy School

Revitalizing Nuclear Security in an Era of Uncertainty

| January 2019

Nuclear security around the world has improved dramatically over the last three decades—which demonstrates that with focused leadership, major progress is possible. But important weaknesses remain, and the evolution of the threat remains unpredictable. The danger that terrorists could get and use a nuclear bomb, or sabotage a major nuclear facility, or spread dangerous radioactive material in a “dirty bomb,” remains too high. The United States and countries around the world need to join together and provide the leadership and resources needed to put global nuclear security on a sustained path of continuous improvement, in the never-ending search for excellence in performance.

A satellite image of Lanzhou Uranium Enrichment Plant in January 2015 (DigitalGlobe).

DigitalGlobe

Journal Article - Nonproliferation Review

The History of Fissile-Material Production in China

| Jan. 23, 2019

This article reconstructs the history of China’s production of highly enriched uranium and plutonium for nuclear weapons based on newly available public sources. It begins with discussion of China’s first set of fissile-material production facilities, which China started building in 1958. It then details the first and second “third-line” construction campaigns, initiated in 1964 and the late 1960s, respectively. Finally, the article considers the policy implications of the history of China’s fissile-material production, particularly its influence on China’s attitude toward negotiating a fissile-material cutoff treaty.

Visitors look at the models of oil tanker shaped floating nuclear reactors and oil rigs showcased at the display booth of China's state-owned China National Nuclear Corporation during the China International Exhibition on Nuclear Power Industry in Beijing. April 27, 2017 (Andy Wong/Associated Press).

Andy Wong/Associated Press

Journal Article - Maritime Issues

China's Planned Floating Nuclear Power Facilities in South China Sea: Technical and Political Challenges

| Nov. 21, 2018

The operation of the fleet of Chinese floating nuclear power plants in the South China Sea carries with it numerous safety and security risks that may have widespread consequences to not only China but also to Southeast Asia and beyond.

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Analysis & Opinions - Bulletin of the Atomic Scientists

Why China stopped making fissile material for nukes

| Mar. 15, 2018

Some western scholars have expressed growing concern about China’s expansion of its nuclear arsenal and what they see as a “sprint to parity” with the United States. One scholar even claimed that China could have built as many as 3,000 nuclear weapons, far above the estimate of Western intelligence agencies, which assume that China has between 200 and 300. As a comparison, the United States and Russia each keep roughly 7,000 nuclear weapons. If China had any interest in parity, that would leave it with an awfully long way to go.

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Journal Article - Nonproliferation Review

China’s Nuclear Modernization: Assuring a Second-Strike Capability

| Feb. 11, 2018

Some experts are increasingly concerned that China’s modernization will lead to a Chinese nuclear “breakout”—a pursuit of a nuclear-warfighting capability or a “sprint to parity” with the United States. David Logan (“Hard Constraints on a Chinese Nuclear Breakout,” Vol. 24, Nos. 1–2, 2017, pp. 13–30) rightly suggests that such a nuclear breakout would be constrained not only by China’s “soft” nuclear policy but also by “hard” technical constraints. I would emphasize that it is the former that has been the first principle guiding China’s nuclear-force development. That some of the “hard” technical constrains have resulted from this “soft” guidance demonstrates China’s commitment to a small deterrent force. It is difficult to imagine that the future development of China’s nuclear force would eventually overthrow these first principles. In fact, there is no evidence that China will change its long-standing nuclear policy.

Report - International Panel on Fissile Materials

China’s Fissile Material Production and Stockpile

| January 2018

China began producing highly enriched uranium (HEU) and plutonium for nuclear weapons in the 1960s and is believed to have halted production the 1980s. Despite the passage of thirty years there has been no official policy declaration in this regard. This report uses newly available public information from Chinese sources to provide an improved reconstruction of the history of China’s production of HEU and plutonium for nuclear weapons. This allows improved estimates of the amount of HEU and plutonium China has produced and of its current stockpiles.

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Analysis & Opinions - The Nautilus Institute

China's Nuclear Spent Fuel Management and Nuclear Security Issues

| Nov. 10, 2017

In this essay, Hui Zhang reviews the status of spent fuel storage in China.  He suggest that China should take steps to improve physical protection, reduce insider threats, promote a nuclear security culture, and improve nuclear cyber security. He also recommends China, South Korea, and Japans’ nuclear security training centers should cooperate and exchange best practices on insider threat reduction, contingency plans for emergency response, and discuss regional cooperation for long-term spent fuel storage, including building a regional center of spent fuel storage.

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Paper

The History of Highly Enriched Uranium Production in China

| July 2017

China initiated its nuclear weapon program in 1955 and began to construct its fissile-material production facilities in the late 1950s. China has produced highly enriched uranium (HEU) for weapons at two complexes: Lanzhou gaseous diffusion plant (GDP, also referred as Plant 504) and Heping GDP (the Jinkouhe facility of Plant 814).

In 1958, China started the construction of the Lanzhou plant with advice from Soviet experts. Moscow withdrew all its experts in August 1960, however, forcing China to become self-reliant. On January 14, 1964, the GDP began to produce 90% enriched uranium, which made possible China’s first nuclear test on 16 October 1964.