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High
level waste, or HLW, is the highly radioactive, chemical
waste material left over when spent nuclear fuel is reprocessed.
HLW can be a solid, a liquid, or a sludgy mixture of the two.
HLW is
produced when spent nuclear fuel is reprocessed to recover uranium
or plutonium. Although the United States no longer reprocesses spent
nuclear fuel, some other countries still do. |
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| HLW Production
at the INL, 1953-1992 |
| Spent
nuclear fuel was reprocessed at the INL from 1953 to 1992,
during a process that involved dissolving spent fuel in acid,
followed by chemically extracting the uranium. The liquid
that remained is very acidic, highly radioactive and contains
hazardous chemicals, which make it a hazardous waste.
Other
activities at the Idaho
Nuclear Technology and Engineering Center (INTEC),
including decontamination activities, rinsing, and laboratory
analysis, produced other liquid wastes that were sent to the
tanks that held high level waste. These other waste
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The
INTEC facility shown above is the storage location for INL's
high level waste.
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liquids
were typically high in sodium content and are thus referred to as
sodium bearing waste. As the sodium bearing waste was inseparably
mixed with the reprocessing waste, the entire volume is classified
as high-level waste.
(Classification
of the sodium bearing waste as either high level waste or mixed
transuranic waste is an issue that will have a huge impact on the
method selected for treatment and is currently being decided in
the legal system.) |
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| Hazardous and Radioactive
= Mixed Waste |
Because
HLW contains components that are hazardous, as well as radioactive
isotopes, it is a mixed
waste. All of the regulations that apply to radioactive
wastes and all of the regulations that apply to hazardous waste
apply to mixed wastes. |
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| Changing Liquid
Waste to Solid Waste |
When
HLW is created, it is almost entirely liquid, although some undissolved
particulate matter can be contained in the liquid. Making liquid
HLW into a solid is a significant goal of the environmental management
plan at INL, and a requirement of the Settlement
Agreement.
Of the
nine million gallons of HLW produced at the INL, most (eight million
gallons) has already been treated to make it a solid and reduce
its volume. The treatment was done between 1962 and 2002 in facilities
called calciners,
and the solid resulting from the treatment is called calcine. |
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| How Much HLW is
at INL? |
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Artist's
rendition of a tank used for storage of sodium-bearing liquid
HLW
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As
of July 2004, the INL's inventory of high level waste is as
follows:
- 995,000 gallons of sodium bearing liquid
waste: it looks like blue Kool-Aid. This liquid is stored
in stainless steel tanks that are within concrete vaults.
- 4,400 cubic meters of calcined waste:
looks like laundry detergent or baking powder. Calcine is
stored in stainless steel bins that are within concrete
vaults.
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| Final
High Level Waste Environmental Impact Statement:
Defining Alternatives
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For
several years, the Idaho has participated in the processes DOE is
using to select alternatives for the treatment, storage, and disposal
of high level waste. DOE issued the final Idaho
High-Level Waste (HLW) and Facilities Disposition Environmental
Impact Statement in September, 2002.
Although
DOE has not issued a Record of Decision for the alternatives
presented in the document, it appears that a decision on some portion
of the waste treatment will be forthcoming after the selection of
a new primary site contractor early in 2005. |
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| Options for Treating
High Level Waste |
The
options for treating high level waste described in the final
EIS are:
- Do nothing, leaving liquid and calcined
waste at INL indefinitely.
- Keep operating the calciner to convert
all liquid waste into calcine and store the calcine at INL
indefinitely.
- Separate the waste into different components
and treat them individually at INL by converting them into
glass or mixing them into grout.
- Treat the waste as a whole by mixing it
into cement or converting it into glass or ceramic at INL.
- Transport calcined waste to Hanford for
treatment and return treated waste to INL or disposal sites
following treatment.
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Calcine
is stored in bin-sets like that shown above. |
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| Alternatives for
Closing HLW Facilities |
The
options for closure and disposal of facilities used to store and
treat high level waste are:
- Do nothing.
- Remove or treat all wastes and contaminated
items so they pose no future risk to workers or the public. This
option would result in radiation levels as if the facilities had
never been in place.
- Close facilities in accordance with state and
federal requirements for landfills.
- Close facilities on a case-by-case basis, removing
structures, decontaminating facilities and monitoring to reduce
risks as necessary to meet health-based levels set for workers
and the public.
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| Where is the HLW
Going to Go? |
| Although the facility
is not yet licensed to accept waste, the U.S. Congress has designated
a national geologic repository location. The facility is located at
Yucca Mountain, in Nye County, Nevada. A Settlement Agreement between
the state of Idaho, DOE, and the Navy requires DOE to have all HLW
treated and ready to leave Idaho by 2035. It's up to DOE to decide
how to treat it and to ensure it is ready to be shipped by that date.
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| Yucca Mountain:
A Possible Answer |
| Ask
people how to manage spent nuclear fuel and high level waste over
the long term and you'll hear different answers. Some believe a
permanent geologic repository should house this waste. Others think
it should go to a central location where it can be monitored and
retrieved if necessary. And others believe it should be stored near
the reactors that create it.
Congress
chose the repository approach in 1982. Following Congress' direction,
DOE is working to license and permit the site—Yucca
Mountain, Nevada—for a national geologic repository for
high-level waste and spent nuclear fuel. |
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Aerial
view of Yucca Mountain, proposed site of the HLW repository |
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| Why a Geologic
Repository? |
| Scientists
have studied methods for permanent disposal of radioactive wastes
for years, focusing on a geologic repository since 1957, when the
National Academy of Sciences recommended
a facility deep underground. In 1992 the Academy reaffirmed that
decision. The question of whether to use a permanent disposal site
or a site where waste could be retrieved is the subject of great
debate. |
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| How Would a Repository
Work? |
| There
is currently spent nuclear fuel and high level waste stored in 34
states. Some of it is at commercial power plants. Other waste is
at federal facilities like the INL. If a repository were to open,
this waste would be sent there and be placed in tunnels within special
disposal containers.
At Yucca
Mountain, tunnels would allow waste to be placed about 1,000 feet
below the surface and 1,000 feet above the water table. The repository
concept relies on barriers to prevent radioactive material from
posing health risks. Some of these barriers are natural, including
the rock type, depth of disposal, and dry climate. Other barriers
would be engineered, human-made ones. The State of Nevada and some
other groups are opposed to the use of Yucca Mountain as the nation's
spent fuel and high-level waste repository. |
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| Why is Idaho Concerned?
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| The
state of Idaho is keenly watching the process of licensing and permitting
for the Yucca Mountain disposal facility. As yet, Yucca Mountain
remains the only possibility for a permanent disposal location for
HLW. If there's no place to take high level waste or spent nuclear
fuel, it will be difficult, if not impossible, to ship it out of
Idaho.
If a permanent disposal
site is not open, these wastes could be taken to an interim site.
But opening an interim site may be as difficult as opening a permanent
one. Risks and public concerns inherent in transporting the waste
might compel DOE to transport the waste only once-to a permanent
disposal site.
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| Current HLW Management
Activities |
| While
the state of Idaho is anxiously waiting for DOE to select a treatment
alternative for INL's HLW, activity is happening behind the scenes
at INL that will help ensure success when the selection is made.
DOE has
been consolidating the remaining liquid sodium bearing waste into
a few tanks at the INTEC tank farm and has been cleaning out the
rest of the tanks. The cleaning process includes pumping out as
much of the waste as possible and then using a high pressure spray
nozzle to spray off the interior of the tank, while sucking out
the residual water and sludge that pools at the bottom.
After
cleaning, samples are taken of whatever remains in the bottom of
the tank, and these samples are analyzed for hazardous and radioactive
chemicals to determine if the tank is clean enough. Once the tanks
are verified to be clean, they are isolated to prevent admitting
any additional waste.
The plan is to fill
the tanks with grout after they are emptied and cleaned, but the
actual grouting has been put on hold. Yet another lawsuit is in
the courts related to whether DOE can grout the tanks or whether
they have to excavate the tanks and treat them as high level waste.
Some groups claim the tanks themselves are HLW, due to the small
amount of residual waste that adheres to the inside of the tanks
after cleaning.
Research
is also underway related to treatment alternatives for the sodium
bearing waste and for the calcine, as well as research on methods
of getting the calcine out of the storage containers so that it
can be treated. The next year or so should hold some interesting
decisions related to treatment of HLW at the INL. |
