disposal of radioactive partitioning- transmutation wastes
TRANSCRIPT
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Disposal Of Radioactive Partitioning-Transmutation Wastes With Separate Disposal Of
High-Heat Radionuclides (90Sr and 137Cs)
Charles W. ForsbergOak Ridge National Laboratory
P.O. Box 2008; Oak Ridge, TN 37831-6179Tel: (865) 574-6783; Email: [email protected]
Nuclear Engineering Department Seminar University of Tennessee
Knoxville, TennesseeJanuary 17, 2001
The submitted manuscript has been authored by a contractor of the U.S. Government under contract DE-AC05-00OR22725. Accordingly, the U.S. Government retains a nonexclusive, royalty-free license to publish or reproduce the published form of this
contribution, or allow others to do so, for U.S. Government purposes.
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Outline
• Principles of Waste Management• Geological Disposal of Wastes• Waste Partitioning and Transmutation (PT)• Separate Management of High-Heat And
Low-Heat Wastes− Very-low-heat Radionuclide (VLHR) Disposal− High-heat Radionuclide (HHR) (90Sr and 137Cs)
Disposal• Conclusions
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Principles Of Waste Management
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The Goal Of Radioactive Waste Management Is To Isolate Radioactive Nuclides Until They
Decay To Acceptable Levels• Radioactivity is harmful to biological
organs• Radionuclides decay to non-radioactive
elements over time− The decay rate for any radionuclide is
measured by its half-life− The half-life is the time during which the
quantity of a radionuclide decays in half− Half-lives vary from a fraction of a second to
millions of years
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The Method Of Isolation Depends Upon The Half-life Of Radionuclides In The Waste
• Very short half-life (days)− Storage method: locked room − Example: short-lived 131I medical isotopes
• Limited half-life (months to years)− Storage method: shallow land burial− Example: low-level waste from reactors
• Long half-live (many years)− Storage method: geological disposal− Example: high-level waste (HLW)
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Geological Disposal Of Wastes
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Yucca Mountain (YM) Repository
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There Are Three Requirements To Assure Safe Disposal
• Avoid physical disturbance and resultant dispersal of the wastes
• Avoid groundwater transport of radionuclides to the open environment
• Limit repository temperatures− Radioactive decay heat increases local
temperatures− Higher temperatures degrade radionuclide
isolation barriers
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Underground Geological Disposal Is Required To Avoid Disturbance And
Dispersal Of Wastes• HLW and spent nuclear fuel (SNF) remain
hazardous for thousands to millions of years
• Surface of the earth changes− Erosion by water, wind, and ice− Accidental intrusion− Deliberate intrusion (Egyptian pyramids)
• Many underground locations are very stable (hundreds of millions of years)
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The Primary Failure Mode Of A Disposal Site Is Dissolution Of Waste In Groundwater And
Transport To The Open Environment• Two methods of radionuclide transport
− Dissolution in groundwater− Colloid transport in groundwater
• Multibarrier systems are used to prevent transport of radionuclides from the waste− Site with low water flow (little water or
impermeable to water flow)− Low solubility waste form− Long-lived waste package (WP)− Diversion of water from the wastes
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Yucca Mountain Waste Package System
ORNL DWG 2000-289
Steel LinedTunnel
Titanium DripShield
Spent NuclearFuel
Waste Package
Invert
Backfill (Optional)
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Radioactive Decay Heat Controls The Size And Cost Of The Repository
• Decay heat is significant [50 to 100 MW(t)]• Repository temperatures must be limited
− Temperatures degrade waste and package− Geology becomes unpredictable
• Temperature limited by spreading the wastes out− More WPs− More tunnels
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If Waste Volume Controlled Repository Design, HLW Repositories Would Be
Small And Cheap
• The proposed YM Repository is designed to accept: − SNF − HLW
• All 70,000 tons of waste could be placed in a cube with dimensions of 30 m on a side
• The cost would be less than a billion dollars
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The 70,000 Metric Tons Of Initial Heavy Metal Of SNF And HLW To The YM Repository Could Fit
Inside A 30-m Cube
ORNL DWG 2000-293
30 m
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Repositories Are Expensive Because Of Radioactive Decay Heat
• Temperature limits control design− Higher temperatures degrade waste forms,
WPs, and geology− Performance is degraded
• Temperature is limited by spreading SNF and HLW over a large area− 11,000 WPs − 100 km of disposal tunnels (5.5 m in diameter)
• SNF and HLW repositories are like automobile radiators--flat to reject heat
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Schematic of the Proposed YM Repository
ORNL DWG 2000-272
EmplacementBlock
MountainRidge
North Ramp
South Ram
p
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The Differences Between The Waste Isolation Pilot Plant (WIPP) And YM Are
A Result Of Decay Heat• WIPP
− Designed for transuranic wastes− Low-heat generation rates− Total cost: a few billion dollars
• YM− Designed for HLW and SNF− Significant heat generation− Total cost: tens of billions of dollars
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Waste P-T
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P-T Is An Advanced Waste Management Concept
• Selected elements are removed from the wastes and destroyed
• Many methods exist for waste destruction− Reactors− Accelerators− Fusion-energy devices
• There are major technical and economic uncertainties
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Three Sets of Radionuclides Are P-T Candidates
• Long-lived toxic radionuclides (99Tc, 129I, 237Np, actinides)
• Fissile isotopes (Np, Pu, Am, Cm)− Minimize repository criticality issues− Minimize safeguards and/or human intrusion
• Long-lived, heat-generating radionuclides (Pu, Am, Cm)− Improve repository performance− Reduce repository size− Reduce repository costs
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Separate Management Of High-Heat And Low-Heat Wastes
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If Repository Cost Or Performance Is To Be Impacted By Changing The Fuel Cycle, Changes
In Decay-Heat Management Are Required
• Five HHRs generate the decay heat− Long-lived (Pu, Am, and Cm)− Shorter-lived (90Sr and 137Cs)
• P-T (if successful) will destroy long-lived HHRs• Destruction of long-lived, heat-generating
radionuclides creates new wastes with characteristics different from previous wastes
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Decay Heat From SNF
ORNL DWG 92C-242R
129X
3X
1.42X
1.31X
1.21X
Sr + Cs
SPENT FUELLESS SrAND Cs
ACTINIDES INSPENT FUEL
ACTINIDE-FREEHIGH-LEVEL
WASTE
TOTAL SPENT FUEL
BASIS: PWR FUEL3.2 wt % U33 GWd/MTIHM1.0 MTIHM
235
2000
100
1010 100 1000
THER
MAL
PO
WER
(W/M
TIH
M)
DECAY TIME AFTER DISCHARGE (years)
1000
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Alternative Repository Concept For Low-Actinide (P-T) Wastes
• Waste is chemically separated into two separate fractions− HHRs (90Sr and 137Cs)− VLHRs
• Design repository with separate sections for disposal of each waste fraction
• Use lower-cost, higher-performance disposal methods, which are optimized for each waste fraction
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Idealized High-Heat Radionuclide Repository(HHRs in SNF at YM Necessitate ~100 kmof Tunnels and ~10,000 Waste Packages)
ORNL DWG 99C-277R
Thin Horizontal Layer
100s - 1000s mHeat
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Idealized Low-Heat Radionuclide Repository
ORNL DWG 99C-278
Spherical WastePackage
(10-100 m diameter)
Waste
100s - 1000s m
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Separate Management Of High-Heat And Low-Heat Wastes: VLHR
Radionuclide Disposal
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VLHRs May Be Disposed Of In Silos
• With low decay heat, no need exists to spread the wastes over kilometers of tunnels and thousands of WPs
• Silos replace WPs− Better performance− Significantly lower costs (up to 10,000 t of SNF
wastes per silo)• Significant European experience with silos
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Swedish SFR Silo For Intermediate-Level Radioactive Waste
ORNL DWG 89C-1100
WasteShippingContainer
Transporter
Silo Crane
TransportedWaste Package
ClayBarrier
Silo(Final WastePackage)
Greater Than 50 MTo Surface
RockCavern
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Repository Performance Is Improved If Silos Replace WPs
• The leaching of radionuclides from wastes is proportional to the water flow though the wastes
• Silos per unit waste volume have smaller cross sections to water flow than do WPs
• Reduced water flow per unit of waste may improve repository performance by several orders of magnitude
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The Geometry Of The Waste (Surface-To-Volume Ratio) Strongly Impacts Radionuclide Releases
ORNL DWG 99C-361R2
25 Units of Waste
Uniform Groundwater Water Flux
Relative RadionuclideReleases
(Groundwater DissolvesRadionuclides toSolubility Limits)
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Silo Disposal Allows For Other Improvements In Performance
• Size and mass allow choice of silo materials to control chemistry− Adjust pH to minimize waste solubility− Adjust oxidation state to minimize waste
solubility• Multiple barriers to water ingress
− Clay− Metal or concrete
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Separate Management Of High-Heat And Low-Heat Wastes: HHR (90Sr and
137Cs) Disposal
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The Properties Of 90Sr And 137Cs Enable The Use Of Low-Cost Disposal Methods
• Shorter half-lives (~30 years)− Simplified prediction of long-term behavior− No expensive long-lived WPs
• Small volumes (4.2 kg/t of SNF)− Package in small capsules− Low-volume borehole disposal becomes viable
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There Are Many Technologies For Managing 90Sr And 137Cs
• Long-term storage• Extended-dry
repository• Modified repository• Saltdiver
• Rock melt• Borehole• Seabed• Shallow-land disposal
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Example 1: HHRs (90Sr and 137Cs) Could Be Stored Until The Decay Heat Is Low
• The storage time is about 300 years• Dry storage (similar to that used for SNF) could be
used • Large experience base--simple technology
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Example 2: HHRs (90Sr and 137Cs) Could Be Disposed Of In An Extended-Dry Repository
• HHRs could be placed in long, horizontal boreholes• Boreholes could be placed close together• Decay heat raises temperatures above boiling point of
water for millennia• No radionuclide transport occurs if there is no liquid
water to transport radionuclides• HHRs decay completely before cool-down of the large
mass of rock• Low-cost boreholes replace expensive tunnels
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HHRs (90Sr and 137Cs) Repository With Boreholes (Rather Than Tunnels) Used To Distribute Decay
Heat Load
ORNL DWG 99C-391R
Access DriftHigh-
Temperature Rock
HorizontalBorehole
HHR Capsules
Hundreds ofmeters
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In Repositories Above The Water Table, The Extended-Dry Repository Concept Creates A “Hydrothermal Umbrella” Over
The HHRs And Diverts Water
ORNL DWG 99C-360R
Condensation Zone
Steam Bubble
High-Heat WasteForm in
Horizontal Borehole
Steam
Liquid Water
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Example 3: Saltdiver Disposal Of HHRs (90Sr and 137Cs)
• Longer term option• Salt domes have depths of up to 10,000 m• Salt is plastic at higher temperatures• High-heat sources (90Sr and 137Cs) could be placed
together in a saltdiver (metal package)• Temperature and weight of saltdiver allow waste to
descend to 10,000 m• Total isolation
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Bedded Salt
Insoluble Materials
Salt Dome With Saltdiver
ORNL DWG 99C-276
Insulation(Control Heat Flux)
Molten Salt(Thin Layer AroundSaltdiver)
HHR Capsules
High-DensityWeights
Saltdiver
Saltdiver Launch Facility
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The Viability Of Separate Management Of HHRs Depends Upon Several Factors
• Repository performance is improved by use of silo disposal
• Improved repository economics− Low-cost 90Sr and 137Cs disposal replace
expensive tunnels− Silos replaces WPs for low-heat wastes
• Added cost: separation of 90Sr and 137Cs• Variants of this option exists any time SNF
is processed (plutonium recycle, no P-T)
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Conventional, Low-Heat Radionuclide (LHR),and High-Heat Radionuclide (HHR) Repositories
ORNL DWG 99C-279R
Conventional Repository for HLW or SNF
LHR Repository Area
Access Drift
High-Temperature
Rock
HorizontalBorehole
HHR Capsules
HHR Repository Area
Disposal Drift
Disposal Drift
LHR WastePackages
HLW or SNFWaste
Packages
Closely SpacedLarge WastePackage
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Conclusions
• Radioactive decay heat controls repository design (cost and performance)
• P-T destroys long-lived HHRs• The destruction of long-lived HHRs
creates new repository options− Separate disposal of 90Sr and 137Cs− Silo disposal of low-heat radionuclides
• Fuel cycle and repository design must be considered together