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New plasma mass filtering method to process nuclear waste.

Physicists at the U.S. Department of Energy's (DOE) Princeton Plasma Physics Laboratory (PPPL) are proposing a new way to process nuclear waste that would reduce both the cost of disposal and the byproducts from the process.

Known as plasma mass filtering, the new mass separation techniques use a plasma-based centrifuge that would supplement chemical techniques. "The safe disposal of nuclear waste is a colossal problem," said Renaud Gueroult, staff physicist at PPPL and lead author of the paper that appeared in the Journal of Hazardous Materials in October.

This work was supported by PPPL's Laboratory Directed Research and Development Program. The immediate motivation for safe disposal is the radioactive waste stored currently at the Hanford Site, a facility in Washington state that produced plutonium for nuclear weapons during the Cold War. The volume of this waste originally totaled 54 million gallons and was stored in 177 underground tanks.

In 2000, Hanford engineers began building machinery that would encase the radioactive waste in glass. The method, known as "vitrification," had been used at another Cold War-era nuclear production facility since 1996. A multibillion-dollar vitrification plant is under construction at the Hanford site.

Since vitrification and disposal in a federal repository of highly radioactive waste are expensive, there is an advantage to first reducing the amount of the highly radioactive waste to be vitrified, with the goal of having to process less volume. The high-level radioactive waste would then be incorporated into the glass matrix.

This vitrified waste is deposited into canisters that measure about 10 feet long and two feet in diameter. These canisters would be sent to a federal repository where the radioactivity dissipates over thousands of years. The low-level waste by-product would be similarly, but less expensively, immobilized in a glass wasteform and disposed of at Hanford.

To reduce the costs, it may be advantageous to reduce the number of high-level glass canisters by packing more waste into each glass canister. To reduce the volume to be vitrified, it would be advantageous to separate the nonradioactive waste, like aluminum and iron, out of the waste, leaving less waste to be vitrified.

However, in its 2014 report, the DOE Task Force on Technology Development for Environmental Management argued that "without the development of new technology, it is not clear that the cleanup can be completed satisfactorily or at any reasonable cost."

The high-throughput, plasma-based, mass separation techniques advanced at PPPL offer the possibility of reducing the volume of waste that needs to be immobilized in glass.

How would a plasma-based mass filter system work? The method begins by atomizing and ionizing the hazardous waste and injecting it into the rotating filter so the individual elements can be influenced by electric and magnetic fields. The filter separates the lighter elements from the heavier ones by using centrifugal and magnetic forces.

The lighter elements are typically less radioactive than the heavier ones and often do not need to be vitrified. Processing of the high-level waste therefore would need fewer high-level glass canisters overall, while the less radioactive material could be immobilized in less costly waste form (e.g., concrete, bitumen).

The technique would also be more widely applicable than traditional chemical-based methods since it would depend less on the nuclear waste's chemical composition. While "the waste's composition would influence the performance of the plasma mass filter in some ways, the effect would most likely be less than that associated with chemical techniques," said Gueroult.

An updated understanding of the complexity of the Hanford problem, combined with an increased appreciation of new ideas, has led to renewed federal interest in waste-treatment solutions. Completion of the main waste processing operations, which was in 2002 projected for 2028, has slipped by 20 years over the last 13 years, and the total cleanup cost is now estimated by the Department of Energy to be greater than 250 billion dollars, according to the DOE Office of Inspector General, Office of Audits and Inspections.

DOE, which has the responsibility of cleaning up the legacy nuclear waste at Hanford and other sites, conducted a Basic Research Needs Workshop on nuclear waste cleanup in July that Fisch and Gueroult attended. The report of that workshop, which is expected to highlight new approaches to the cleanup problem, is due out this fall.

Source: AZo Cleantech
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Publication:Nuclear Waste News
Date:Dec 18, 2015
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