Using engineered zeolites, they
are able to captured gaseous mercury and bind it integrally into the zeolites allowing
excellent disposal prospects. The
obvious hope is to apply the methodology or other waste products of nuclear fission.
Zeolites and their related
technologies where always the best available avenue for mastering intractable waste
products. The crystalline form means
that the active ions are going no where and a strong bonder will sponge up free
ions handily. In this case it was necessary
to tightly engineer the solution.
It has been a slow haul, but it
is good to see folks working on solutions.
Sandia chemists find new material to remove radioactive gas from spent
nuclear fuel
by Staff Writers
Sandia chemist Tina Nenoff heads a team of researchers focused on
removal of radioactive iodine from spent nuclear fuel. They identified a
metal-organic framework that captures and holds the volatile gas, a discovery
that could be used for nuclear fuel reprocessing and other applications. (Photo
by Randy Montoya).
Research by
a team of Sandia chemists could impact worldwide efforts to produce clean, safe
nuclear energy and reduce radioactive waste.
The Sandia researchers have used metal-organic frameworks (MOFs)
to capture and remove volatile radioactive gas from spent nuclear fuel.
"This is one of the first attempts to use a MOF for iodine capture,"
said chemist Tina Nenoff of Sandia's Surface and Interface Sciences Department.
The discovery could be applied to nuclear fuel reprocessing or
to clean up nuclear reactor accidents. A characteristic of nuclear energy is
that used fuel can be reprocessed to recover fissile materials and provide
fresh fuel for nuclear power plants. Countries such as France , Russia
and India
The process also reduces the volume of high-level wastes, a key concern
of the Sandia researchers. "The goal is to find a methodology for highly
selective separations that result in less waste being interred," Nenoff
said.
Part of the challenge of reprocessing is to separate and isolate
radioactive components that can't be burned as fuel. The Sandia team focused
on removing iodine, whose isotopes have a half-life of 16 million years, from
spent fuel.
They studied known materials, including silver-loaded zeolite, a
crystalline, porous mineral with regular pore openings, high surface area
and high mechanical, thermal and chemical stability. Various zeolite frameworks
can trap and remove iodine from a stream of spent nuclear fuel, but need added
silver to work well.
"Silver attracts iodine to form silver iodide," Nenoff said. "The
zeolite holds the silver in its pores and then reacts with iodine to trap
silver iodide."
But silver is expensive and poses environmental problems, so the team
set out to engineer materials without silver that would work like
zeolites but have higher capacity for the gas molecules. They explored why and
how zeolite absorbs iodine, and used the critical components discovered to find
the best MOF, named ZIF-8.
"We investigated the structural properties on how they work and
translated that into new and improved materials," Nenoff said.
MOFs are crystalline, porous materials in which a metal center is bound
to organic molecules by mild self-assembly chemical synthesis. The choice of
metal and organic result in a very specific final framework.
The trick was to find a MOF highly selective for iodine. The Sandia
researchers took the best elements of the zeolite Mordenite - its pores, high
surface area, stability and chemical absorption - and identified a MOF that can
separate one molecule, in this case iodine, from a stream of molecules. The MOF
and pore-trapped iodine gas can then be incorporated into glass waste for
long-term storage.
The Sandia team also fabricated MOFs, made of commercially available
products, into durable pellets. The as-made MOF is a white powder with a
tendency to blow around. The pellets provide a stable form to use without loss
of surface area, Nenoff said.
Sandia has applied for a patent on the pellet technology, which could
have commercial applications.
The Sandia researchers are part of the Off-Gas Sigma Team, which is led
by Oak Ridge Idaho
The project began six years ago and the Sigma Team was formalized in
2009. It is funded by the U.S.
Sandia's iodine and MOFs research was featured in two recent articles
in the Journal of the American Chemical Society authored by Nenoff and team
members Dorina Sava, Mark Rodriguez, Jeffery Greathouse, Paul Crozier, Terry
Garino, David Rademacher, Ben Cipiti, Haiqing Liu, Greg Halder, Peter Chupas, and
Karena Chapman. Chupas, Halder and Chapman are from Argonne .
"The most important thing we did was introduce a new class of
materials to nuclear waste remediation," said Sava ,
postdoctoral appointee on the project.
Nenoff said another recent paper in Industrial and Engineering
Chemistry Research shows a one-step process that incorporates MOFs with iodine
in a low-temperature, glass waste form. "We have a volatile off-gas
capture using a MOF and we have a durable waste form," Nenoff said.
Nenoff and her colleagues are continuing their research into new and
optimized MOFs for enhanced volatile gas separation and capture.
"We've shown that MOFs have the capacity to capture and, more
importantly, retain many times more iodine than current materials
technologies," said Argonne 's Chapman.
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