Waste forms from the electrometallurgical treatment of DOE spent fuel: Production and general characteristics

Engineered Components for Spent Fuel Radioactive Waste Isolation Systems—are They Technically Justified?

MRS Proceedings ◽

10.1557/proc-11-619 ◽

1981 ◽

Vol 11 ◽

Author(s):

H. C. Burkholder

Keyword(s):

United States ◽

Radioactive Waste ◽

Release Rate ◽

The United States ◽

Radioactive Waste Disposal ◽

Radionuclide Transport ◽

Spent Fuel ◽

Isolation System ◽

Waste Forms ◽

Isolation Systems

In response to draft radioactive waste disposal standards, R&D programs have been initiated in the United States which are aimed at developing and ultimately using radionuclide transport-delaying (e.g., long-lived waste containers) and radionuclide transport-controlling (e.g., very low release rate waste forms) engineered components as part of the isolation system. Before these programs proceed significantly, it seems prudent to evaluate the technical justification for development and use of sophisticated engineered components in radioactive waste isolation.

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A Comparison of the Performance of Nuclear Waste Glasses by Modeling

MRS Proceedings ◽

10.1557/proc-112-713 ◽

1987 ◽

Vol 112 ◽

Cited By ~ 8

Author(s):

B. Grambow ◽

D. M. Strachan

Keyword(s):

Nuclear Waste ◽

Nuclear Reactors ◽

Liquid Waste ◽

Spent Fuel ◽

High Level Liquid Waste ◽

Geologic Repository ◽

Waste Forms ◽

The Earth ◽

Soluble Solid ◽

High Level

The reprocessing of spent fuel from nuclear reactors and processing of fuels for defense purposes have generated large volumes of high-level liquid waste that need to be immobilized prior to final storage. For immobilization, the wastes must be converted to a less soluble solid, and, although other waste forms exist, glass currently appears to be the choice for the transuranic-containing portion of the reprocessed waste. Once produced, this glass will be sent in canisters to a geologic repository located some 200 to 500 m below the surface of the earth.

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Characterization of Mechanical Strengths for Simulated High-Level Waste Forms

MRS Proceedings ◽

10.1557/proc-176-433 ◽

1989 ◽

Vol 176 ◽

Cited By ~ 1

Author(s):

Hiroshi Igarashi ◽

Takeshi Takahashi

Keyword(s):

Fracture Toughness ◽

Glass Ceramic ◽

Bending Strength ◽

Liquid Waste ◽

High Level Waste ◽

Spent Fuel ◽

High Level Liquid Waste ◽

Waste Forms ◽

High Level ◽

Mechanical Strengths

ABSTRACTWaste forms have been developed and characterized at PNC (Power Reactor and Nuclear Fuel Development Corporation)to immobilize high-level liquid waste generated from the reprocessing of nuclear spent fuel.Mechanical strength tests were excecuted on simulated solidified highlevel waste forms which were borosilicate glass and diopside glass-ceramic. Commercial glass was tested for comparison. Measured strengths were three-point bending strength,uniaxial compressive strength,impact strength by falling weight method,and Vickers hardness. Fracture toughness and fracture surface energy were also measured by both notch-beam and indentation technique.The results show that mechanical strengths of waste glass form are similar and that the glass ceramic form has the higher fracture toughness.

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Interpreting Uranyl Mineral Diffraction Patterns

Microscopy and Microanalysis ◽

10.1017/s1431927600022923 ◽

1998 ◽

Vol 4 (S2) ◽

pp. 560-561

Author(s):

Edgar C. Buck

Keyword(s):

Corrosion Behavior ◽

Nuclear Waste ◽

Equatorial Plane ◽

Waste Form ◽

Spent Fuel ◽

Secondary Phases ◽

Form Complex ◽

Waste Forms ◽

Diffraction Patterns ◽

Nuclear Waste Forms

Secondary phases that form during the corrosion of nuclear waste forms may influence both the rate of waste form dissolution and the release of radionuclides [1]. The identification of these phases is critical in developing models for the corrosion behavior of nuclear waste forms. In particular, the secondary uranyl (VI) minerals that form during waste form alteration may control uranium solubility and release of radionuclides incorporated into these phases [2].The U6+ cation in uranyl minerals is almost always present as a linear (UO2)2+ ion [3]. This uranyl (Ur) ion is coordinated by four, five, or six anions (ϕ) in the equatorial plane resulting in the formation of square (Urϕ4), pentagonal (Urϕ5), and hexagonal (Urϕ6) bipyramids, respectively [3]. These bipyramid polyhedra may polymerize to form complex infinite sheet structures. The linking of Urϕ5 is observed in a number of uranyl minerals formed during waste glass and spent fuel corrosion [2,4], such as weeksite [Na,K(UO2)2(Si205)3*4H2O] and β-uranophane [Ca[(UO2)(SiO3OH)]2*5H2O].

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The Strategy of the Belgian Nuclear Research Centre in the Area of High-Level Waste Form Compatibility Research

11th International Conference on Environmental Remediation and Radioactive Waste Management, Parts A and B ◽

10.1115/icem2007-7232 ◽

2007 ◽

Author(s):

Karel Lemmens ◽

Christelle Cachoir ◽

Elie Valcke ◽

Karine Ferrand ◽

Marc Aertsens ◽

...

Keyword(s):

Nuclear Research ◽

Waste Form ◽

Research Centre ◽

High Level Waste ◽

Spent Fuel ◽

National Agency ◽

Waste Forms ◽

In Situ Experiments ◽

High Level

The Belgian Nuclear Research Centre (SCK•CEN) has a long-standing expertise in research concerning the compatibility of waste forms with the final disposal environment. For high level waste, most attention goes to two waste forms that are relevant for Belgium, namely (1) vitrified waste from the reprocessing of spent fuel, and (2) spent fuel as such, referring to the direct disposal scenario. The expertise lies especially in the study of the chemical interactions between the waste forms and the disposal environment. This is done by laboratory experiments, supported by modeling. The experiments vary from traditional leach tests, to more specific tests for the determination of particular parameters, and highly realistic experiments. This results in a description of the phenomena that are expected upon disposal of the waste forms, and in quantitative data that allow a conservative long-term prediction of the in situ life time of the waste form. The predictions are validated by in situ experiments in the underground research laboratory HADES. The final objective of these studies, is to estimate the contribution of the waste form to the overall safety of the disposal system, as part of the Safety and Feasibility Case, planned by the national agency ONDRAF/NIRAS. The recent change of the Belgian disposal concept from an engineered barrier system based on the use of bentonite clay to a system based on a concrete buffer has caused a reorientation of the research programme. The expertise in the area of clay-waste interaction will however be maintained, to develop experimental methodologies in collaboration with other countries, and as a potential support to the decision making in those countries where a clay based near field is still the reference. The paper explains the current R&D approach, and highlights some recent experimental set-ups available at SCK•CEN for this purpose, with some illustrating results.

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Irradiation and Cooling Process Effects on Material Barrier Analysis Based on Plutonium Composition of LWR

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.772.513 ◽

2013 ◽

Vol 772 ◽

pp. 513-518

Author(s):

Sidik Permana ◽

Novi Trian ◽

Abdul Waris ◽

Su'ud Zaki ◽

I. Mail ◽

...

Keyword(s):

Nuclear Fuel ◽

Decay Time ◽

Cooling Time ◽

Fuel Burnup ◽

Fuel Utilization ◽

Spent Fuel ◽

Nuclear Facilities ◽

Fuel Production ◽

Plutonium Isotopes ◽

Plutonium Production

Nuclear fuel utilization program from front-end up to back-end processes especially spent fuel management have been monitored and safeguarded by the IAEA in order to ensure the utilization of nuclear fuels from all nuclear facilities including nuclear fuel reprocessing facilities are dedicated only for civil and peaceful purposes. Nuclear fuel production processes including reactor criticality condition is one of the major topics in term of nuclear fuel sustainability which related to energy security issues. Meanwhile, reduction level or preventing processes of nuclear fuel utilization from its potential risk from nuclear explosive purposes should be also strengthened and prioritized. To increase the intrinsic proliferation resistance of nuclear fuel, one of the potential ways is by increasing the material barrier level such as isotopic barrier. In case of plutonium, increasing the intrinsic properties of plutonium isotopes can be used by increasing material barrier of even mass number (Pu-238, Pu-240 and Pu-242). In this study, the effect of different irradiation process during reactor operation which related to discharged fuel burnup have been used and decay time to analyzed its dependeny to plutonium production as well as plutonium production dependency to decay or cooling time processes. Fuel production analysis of the reactor are based on the spent fuel of light water reactor (LWR) with different discharged fuel burnup (33 GWd/t, 50 GWd/t and 60 GWd/t) and different decay or cooling time process (1 to 30 years cooling time). Fuel behavior optimization of LWR design are obtained by using ORIGEN code by employing some modules for analyzing fuel production dependencies to burnup and decay time processes. In this study, two parameters for investigating the material barriers are adopted such as decay heat (DH) and spontaneous fission neutron (SFN) compositions. The compositions of DH and SFN are sensitive to the composition of isotopic plutonium especially more sensitive to even mass plutonium composition. Higher discharged fuel burnup level produces more even mass plutonium compositions and effectively reduce Pu-239 production because of more fissile Pu-239 are consumed for higher burnup. Isotopic Pu-238 gives the highest DH contributor, while Isotope Pu-240 obtains the highest contribution of SFN followed by other plutonium isotopes. DH and SFN compositions of plutonium can be increased effectively by increasing burnup process. Longer decay time is also effective to increase SFN compositions because of its dependency to all even mass plutonium while it gives less DH compositions because of its dependency to the contribution of Pu-238.

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Development of New Waste Forms to Immobilize Iodine-129 Released from a Spent Fuel Reprocessing Plant

Advances in Science and Technology ◽

10.4028/www.scientific.net/ast.73.158 ◽

2010 ◽

Vol 73 ◽

pp. 158-170 ◽

Cited By ~ 16

Author(s):

Hiromi Tanabe ◽

Tomofumi Sakuragi ◽

Kenji Yamaguchi ◽

Taemi Sato ◽

Hitoshi Owada

Keyword(s):

Radioactive Wastes ◽

Behavior Modeling ◽

Spent Fuel ◽

Waste Forms ◽

Reducing Conditions ◽

Geological Repository ◽

Spent Fuel Reprocessing ◽

Immobilization Techniques ◽

Reprocessing Plant ◽

Fuel Reprocessing

I-129 is a very long-lived radionuclide that is released to an off-gas stream when spent fuels are dissolved at a reprocessing plant. An iodine filter can capture I-129 in the form of AgI. However, because AgI is unstable under the reducing conditions of a geological repository and I-129 has a very long half-life, I-129 can migrate to the biosphere. These characteristics make I-129 a key radionuclide for the safety assessment of a geological disposal of radioactive wastes generated from a reprocessing plant (TRU wastes). To improve disposal safety, several new waste forms have been developed to confine I-129 for a very long period in order to reduce the leaching of I-129 from radioactive wastes. These new waste forms have technical objectives of solidifying more than 95% of I-129 into the waste form and achieving a leaching rate of less than 10-5/y. Several iodine immobilization techniques have been examined. This paper presents experimental results concerning the treatment process, leaching behavior, modeling, and related elements of these immobilization techniques.

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Source Trends for Performance Assessment of HLW Glass and Spent Fuel as Waste Forms

MRS Proceedings ◽

10.1557/proc-506-141 ◽

1997 ◽

Vol 506 ◽

Cited By ~ 3

Author(s):

B. Grambow

Keyword(s):

Mass Transfer ◽

Performance Assessment ◽

Source Term ◽

Reaction Rates ◽

Dissolution Mechanism ◽

Experimental Measurements ◽

Source Terms ◽

Spent Fuel ◽

Fuel Oxidation ◽

Waste Forms

ABSTRACTwith respect to the state of validation for source term development. Consequences of the various mechanism on mass half lives of the waste forms are calculated with analytical equations. For glass the largest uncertainty stems from the yet unclear dissolution mechanism under silica saturated conditions. Source terms based on silica solubility coupled to Si-mass transfer are probably neither conservative nor realistic. For spent fuel the largest uncertainty is in the extrapolation of radiolytic fuel oxidation for long periods of time. Considering the uncertainties involved, reaction rates cannot yet be extrapolated reliably to values much lower than the lowest reliable experimental measurements.

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Stability of Cubic Zirconia in a Granitic System Under High Pressure & Temperature

MRS Proceedings ◽

10.1557/proc-1107-59 ◽

2008 ◽

Vol 1107 ◽

Author(s):

Fergus G.F. Gibb ◽

Boris E. Burakov ◽

Kathleen J. Taylor ◽

Yana Domracheva

Keyword(s):

Radioactive Wastes ◽

Waste Form ◽

Deep Borehole ◽

Spent Fuel ◽

Zirconia Crystal ◽

Cubic Zirconia ◽

Inert Matrix ◽

Waste Forms ◽

Glassy Sample ◽

Container Material

AbstractCubic zirconia is a well known, highly durable material with potential uses as an actinide host phase in ceramic waste forms and inert matrix fuels and in containers for very deep borehole disposal of some highly radioactive wastes. To investigate the behaviour of this material under the conditions of possible use, a cube of ∼ 2.5 mm edge was made from a single crystal of yttriastabilized cubic zirconia doped with 0.3 wt.% CeO2. The cube was enclosed in powdered granite within a gold capsule and a small amount of H2O added before sealing. The sealed capsule was held for 4 months in a cold-seal pressure vessel at a temperature of 780°C and a pressure 150 MPa, simulating both the conditions of a deep borehole disposal involving partial melting of the host rock and the conditions under which the actinide waste form might be encapsulated in granite prior to disposal. At the end of the experiment the quenched, largely glassy, sample was cut into thin slices and studied by optical microscopy, EMPA, SEM and cathodoluminescence methods. The results show that no corrosion of the zirconia crystal or reaction with the granite melt occurred and that no detectable diffusion of elements, including Ce, in or out of the zirconia took place on the timescale of the experiment. Consequently, it appears that cubic zirconia could perform most satisfactorily as both an actinide host waste form for encapsulation in solid granite for very deep disposal and as a container material for deep borehole disposal of highly radioactive wastes (HLW), including spent fuel.

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Synroc development—Past and present applications

MRS Energy & Sustainability ◽

10.1557/mre.2017.9 ◽

2017 ◽

Vol 4 ◽

Cited By ~ 8

Author(s):

Eric R. Vance ◽

Dorji T. Chavara ◽

Daniel J. Gregg

Keyword(s):

Glass Ceramic ◽

Intermediate Level ◽

Waste Form ◽

Spent Fuel ◽

Process Technology ◽

Technology Platform ◽

Ceramic Waste ◽

Waste Forms ◽

Produce Glass ◽

Waste Loading

ABSTRACTSynroc has evolved over the last 40 years from the titanate full-ceramics developed in the late 1970s to a technology platform that can be applied to produce glass, glass–ceramic, and ceramic waste forms and where there are distinct advantages in terms of waste loading and suppressing volatile losses.A first of a kind Synroc plant for immobilizing intermediate level waste arising from Mo-99 production is currently in detailed engineering at ANSTO.Since the year 2000, Synroc has evolved from the titanate full-ceramics developed in the late 1970s to a technology platform that can be applied to produce glass, glass–ceramic, and ceramic waste forms and where there are distinct advantages in terms of waste loading and suppressing volatile losses. Furthermore recent efforts have focused strongly on waste form development for plutonium-bearing wastes in the UK, for different options for the immobilization of Idaho calcines and most recently developing an engineered waste form for the intermediate level wastes arising from 99Mo production, for the Australian Nuclear Science and Technology Organisation (ANSTO). A variety of other studies are currently in progress, including engineered waste forms for spent fuel and investigating the proliferation risks for titanate-based waste forms containing highly enriched uranium or plutonium. This paper also attempts to give some perspective on Synroc waste forms and process technology development in the nuclear waste management industry.

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