Hui Zhang presented "Spent Nuclear Fuel Reprocessing in China" at the 15th PIIC Beijing Seminar on International Security: Nuclear Nonproliferation and Cooperation.

This important book analyzes nuclear weapon and energy policies in Asia, a region at risk for high-stakes military competition, conflict, and terrorism. The contributors explore the trajectory of debates over nuclear energy, security, and nonproliferation in key countries—China, India, Japan, Pakistan, South Korea, Taiwan, Vietnam, and other states in the Association of Southeast Asian Nations (ASEAN).

This important book analyzes nuclear weapon and energy policies in Asia, a region at risk for high-stakes military competition, conflict, and terrorism. The contributors explore the trajectory of debates over nuclear energy, security, and nonproliferation in key countries—China, India, Japan, Pakistan, South Korea, Taiwan, Vietnam, and other states in the Association of Southeast Asian Nations (ASEAN).

"On March 31, Chinese President Xi Jinping will be among world leaders attending the fourth and last Nuclear Security Summit in Washington, D.C., where they will try to strengthen nuclear security to deal with the evolving threat of nuclear terrorism. Such efforts are badly needed, in light of the facts that there have been approximately 20 documented cases of theft or loss of highly enriched uranium or plutonium (although more may have occurred) since the early 1990s,and that there are nearly 2,000 metric tons of dangerous nuclear materials scattered across hundreds of sites around the globe..."

Hui Zhang presented "China’s Civilian Reprocessing Programs" to the International Panel on Fissile Materials meeting in Washington, D.C., March 14-15, 2016.

New public information allows a fresh estimate of China's current and under-construction uranium enrichment capacity. This paper uses open source information and commercial satellite imagery to identify and offer estimates of the capacity of China's 10 operating enrichment facilities, located at 4 sites, using centrifuge technology most likely based on adapting Russian technology. The total currently operating civilian centrifuge enrichment capacity is estimated to be about 4.5 million separative work units/year (SWU/year), with additional capacity estimated to be about 2 million SWU/year under construction. Also China could have an enrichment capacity of around 0.6 million SWU/year for non-weapon military uses (i.e., naval fuel) or dual use. These estimates are much larger than previous public estimates of China's total enrichment capacity. Further expansion of enrichment capacity may be likely since China will require about 9 million SWU/year by 2020 to meet the enriched uranium fuel needs for its planned nuclear power reactor capacity of 58 gigawatts-electric (GWe) by 2020 under its policy of self-sufficiency in the supply of enrichment services.

Based on satellite imagery, Chinese publications, and discussions with Chinese experts, This report suggests that China has much more civilian enrichment capacity than previously thought, and even more is on the way. If these new estimates are correct, China has enough enrichment capacity to meet its nuclear power fuel requirements for the coming decade and beyond. Further, China will have excess enrichment capacity and will likely become a net exporter of commercial enrichment services.

"Plutonium was first separated by the United States during the Second World War. Uranium was loaded into nuclear reactors, irradiated, cooled, and then chemically “reprocessed” in another facility to recover the plutonium. The reactors and the reprocessing plant were built as part of the secret atomic bomb project. Since then, eight other countries also have produced and separated plutonium for weapons..."

Official plans in China call for a three-fold increase in nuclear energy by 2020, and much more is under consideration for the coming decades. How will China get the uranium it needs to feed its ambitious nuclear energy plans for the coming decades? This report suggests that between domestic uranium mining, uranium purchased on the international market, and uranium mined by Chinese-owned companies overseas, the security of China’s uranium supply will not pose a challenge to China’s nuclear power development, even under the most ambitious scenarios for growth.

"Baldev Raj and P.R. Vasudeva Rao have argued that reprocessing and fast breeder reactors are necessary for the long-term sustainability of nuclear power. Indeed, fast breeder reactors' potential to produce more fuel than they consume has held an attraction since the advent of nuclear power, especially to those who envision a time when uranium will no longer be available cheaply. Unfortunately, several decades of experience have shown that plutonium recycling systems are much more costly and much less reliable than water-cooled reactors. If establishing sustainable nuclear power means successfully managing important issues such as nuclear safety and proliferation resistance, while also achieving economic competitiveness, minimizing production of radioactive waste, and using natural resources wisely, breeder reactors and plutonium recycling still have far to go before they can meaningfully contribute..."