Plutonium Signatures in Molten-Salt Reactor Off-Gas Tank and Safeguards Considerations

Dunkle, Nicholas; Wheeler, A.D.; Richardson, Jarod; Bogetic, Sandra; Chvála, O.; Skutnik, Steven E.

doi:10.3390/jne4020028

Cited by 3 publications

(4 citation statements)

References 30 publications

(55 reference statements)

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“…The design will dictate the waste generation. For instance, the off-gas system could be enclosed for some reactor designs or have limited throughput (Dunkle et al, 2023), but most will have a flowing cover gas that continuously removes volatile radionuclides similarly to the Molten Salt Reactor Experiment (MSRE) at Oak Ridge National Laboratory (Guymon, 1973). Online processing could include removal of insoluble materials such as graphite particles and noble metals or actinide recovery from the liquid phase.…”

Section: Waste Generationmentioning

confidence: 99%

Cradle to grave: the importance of the fuel cycle to molten salt reactor sustainability

McFarlane

2024

Front. Nucl. Eng.

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Advanced reactor technologies are being considered for the next-generation of nuclear power plants. These plants are designed to have a smaller footprint, run more efficiently at higher temperatures, have the flexibility to meet specific power or heating needs, and have lower construction costs. This paper offers a perspective on molten salt reactors, promoted as having a flexible fuel cycle and close-to-ambient pressure operation. A complexity introduced by reducing the reactor footprint is that it may require low-enriched fuel for efficient operation, available from enrichment of the feed salt or by reusing actinides from existing used nuclear fuel (UNF). Recycling UNF has the potential to reduce high-level waste, if done correctly. Release limits from UNF processing are stringent, and processes for waste reduction, fission gas trapping, and stable waste-form generation are not yet ready for commercial deployment. These complex processes are expensive to develop and troubleshoot because the feed is highly radioactive. Thus, fuel production and supply chain development must keep abreast of reactor technology development. Another aspect of reactor sustainability is the non-fuel waste streams that will be generated during operation and decommissioning. Some molten salt reactor designs are projected to have much shorter operational lifetimes than light-water reactors: less than a decade. A goal of the reactor sustainability effort is to divert these materials from a high-level waste repository. However, processing of reactor components should only be undertaken if it reduces waste. Economic and environmental aspects of sustainability are also important, but are not included in this perspective.

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Section: Waste Generationmentioning

confidence: 99%

Cradle to grave: the importance of the fuel cycle to molten salt reactor sustainability

McFarlane

2024

Front. Nucl. Eng.

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“…There is a strong need for a comprehensive assessment of these parameters throughout the reactor lifetime since their evolution can significantly affect the safety margins of the reactor. Considering the importance of evaluation of the MSRs burnup and its reactor core-related parameters, various research studies have been conducted that belong to one of the following categories: all employing burnup as the main parameter; (i) burnup and core inventory calculations , (ii) burnup optimization [15,[22][23][24], (iii) salt clean-up systems [25][26][27][28][29], and, finally, (iv) waste transmutation [30][31][32][33][34].…”

Section: Introductionmentioning

confidence: 99%

On the Employment of a Chloride or Floride Salt Fuel System in Advanced Molten Salt Reactors, Part 2; Core Inventory, Fuel Burnup, and Salt Clean-Up System

Noori-kalkhoran,

Jain,

Powell

et al. 2024

Energies

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Breed and Burn (B&B) fuel cycle in molten salt reactors (MSRs) qualifies this reactor type as one of the best candidates to be developed for the Gen-IV R&D program. This feature can be approached by employing a closed fuel cycle and application of a molten salt reactor as a spent nuclear fuel burner; the features promise sustainable and clean energy in the future. In this study, a complete package has been developed to calculate core inventory, fuel burnup, and salt clean-up systems of molten salt reactors during their lifetime. To achieve this, the iMAGINE-3BIC package (“iMAGINE 3D-Reg Burnup & Inventory Calculator package”) has been developed in MATLAB R2023a by employing a CINDER90 module of MCNPX 2.7 for burnup-calculation and multi-linear regression method (MLR). The package can estimate the core inventory (concentration of 25 actinides and 245 non-actinides elements) and the burnup of the reactor core during MSR lifetime (up to 100 years) while optimizing the computational resources (time, CPU and RAM), and it can even be hassle-freely executed on standalone PCs in an appropriate time due to its generous database. In addition, the salt clean-up module of the iMAGINE-3BIC package can be employed to evaluate the effects of the salt clean-up system on the above parameters over the MSRs’ lifetime. Finally, the iMAGINE-3BIC package has been applied to an iMAGINE reactor core design (University of Liverpool, UK—chloride-based salt fuel system) and an EVOL reactor core design (CNRS, Grenoble, France, fluoride-based salt fuel system) to evaluate and compare the performance of chloride/fluoride-based salt fuel MSRs from the point of burnup, core inventory, and salt clean-up systems. The results confirm that while a chloride-based salt fuel system has some advantages in less dependency on the salt clean-up system and fewer poisoning elements inventory, the fluoride-based system can achieve higher burnup during the reactor lifetime. The outcome of this study, along with the first part of this article, provides evidence to support the neutronic decision matrix as well as the pros and cons of employing chloride- or fluoride-based fuel systems in MSR cores.

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“…Specifically, the use of ultraviolet–visible (UV–vis) absorbance and Raman spectroscopy is discussed for the characterization of uranium behavior within chloride-based melts. UV–vis and Raman are well-known techniques for characterizing actinides and lanthanides in a wide range of chemical systems. ,− Furthermore, the integration of these techniques into the harsh molten salt environment has been well demonstrated on the small scale. ,− However, this work aims to explore the poorly understood realm of U behavior under complex conditions. Particularly, in chloride-based salts without active redox control, the dynamic speciation and redox behavior of U is unknown.…”

Section: Introductionmentioning

confidence: 99%

“…Molten salt reactors (MSRs) are an example of this . Notably, these reactors may also have the option of online processing, allowing for internal recycling of fuel and possibly harvesting of critical materials. − …”

Section: Introductionmentioning

confidence: 99%

Exploring the Complex Chemistry of Uranium within Molten Chloride Salts

Branch,

Felmy,

Schafer Medina

et al. 2023

Ind. Eng. Chem. Res.

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Harsh environments represent a unique opportunity to explore new frontiers in chemistry while developing novel tools to meet global needs. Exploring the chemistry of uranium within molten salts is a key example. Actinide chemistry within the highly ionic environment of a molten salt is poorly understood, particularly in the presence of common salt impurities or without active oxidation state control. Delving into this chemistry can provide new insight into actinide and f-electron interactions. Furthermore, expanding our chemical knowledge can also enable advances in the deployment of molten salt reactors or molten salt recycle schemes. Both molten salt applications aim toward providing green and reliable energy as well as critical materials for the world. Here, the utilization of visible absorbance and Raman spectroscopies to understand and quantify U within chloride-based salt eutectics is discussed. Furthermore, machine learning techniques in the form of chemometric modeling are developed and described, providing advanced analytical tools to quantify and characterize the U present. These tools are then leveraged to monitor and explore the dynamic fundamental chemistry of U within chloride-based salt melts without active oxidation state control.

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Plutonium Signatures in Molten-Salt Reactor Off-Gas Tank and Safeguards Considerations

Cited by 3 publications

References 30 publications

Cradle to grave: the importance of the fuel cycle to molten salt reactor sustainability

Cradle to grave: the importance of the fuel cycle to molten salt reactor sustainability

On the Employment of a Chloride or Floride Salt Fuel System in Advanced Molten Salt Reactors, Part 2; Core Inventory, Fuel Burnup, and Salt Clean-Up System

Exploring the Complex Chemistry of Uranium within Molten Chloride Salts

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