Modeling and analysis of the tritium fuel cycle for ARC- and STEP-class D-T fusion power plants

The neutronics performance of a tokamak has been identified as an important factor in designing a fusion power plant. The design of the tokamak should not only meet operational parameters such as sufficient tritium breeding, but also safety parameters such as low structural material activation. This paper investigates the impacts of the neutronics metrics for the ARC-class tokamak, a compact tokamak with an immersion blanket, by perturbing the first five layers of structural material - first wall, inner vacuum vessel, coolant salt channel, neutron multiplier, and outer vacuum vessel. The goal of this work is to provide insight into shaping and scaling the flux on each layer to obtain optimized operational and safety metrics through quantification of the responses from each perturbation.Results show that increased first wall thickness can increase the tritium breeding ratio (TBR) in specific configurations with high Li6 enrichments and that vacuum vessels decrease TBR for low-Li6 enrichment configurations. It was also found that the neutron multiplier can either increase or decrease TBR depending on the configuration. The response of metrics to the change in layer thickness and enrichment also varies depending on the vacuum vessel material. The integral impacts of Li6 enrichment, layer thicknesses, and vacuum vessel material choice are investigated and presented in this paper.

Section: Tritium Breeding Ratiomentioning

confidence: 99%

Integral analysis of the effect of material dimension and composition on tokamak neutronics ^*

Bae,

Young,

Borowiec

et al. 2024

“…Regarding safety, a higher quantity of the radioactive tritium may be trapped in components using a tungsten first wall. Economically, a higher trapped inventory means less of the tritium produced by the breeding blanket can be recovered, meaning a higher startup inventory and larger tritium breeding ratio will be required for the same tritium doubling time [4]. Furthermore, larger tritium inventories will produce more helium through decay, resulting in more bubble formation, contributing to embrittlement effects, and reducing the lifespan of the plasma-facing components.…”

Section: Discussionmentioning

confidence: 99%

“…Accurate simulation of the hydrogen isotope transport is imperative to ensure safe operation and optimal performance of the FPP's using tritium. Furthermore, accurate simulations of subcomponents can better inform system-level fuel cycle models, potentially leading to better economic performances of an FPP [4,5]. Tritium production in nuclear fusion devices presents a concern for designers due to its permeability through materials, and its radioactive nature requires accurate monitoring.…”

Section: Introductionmentioning

confidence: 99%

Modelling neutron damage effects on tritium transport in tungsten

Dark,

Delaporte-Mathurin,

Schwarz-Selinger

et al. 2024

Self Cite

A damage-induced hydrogen trap creation model is proposed, and parameters for tungsten are identified using experimental data. The methodology for obtaining these parameters using thermo-desorption analysis spectra data is outlined. Self-damaged and optionally annealed tungsten samples have undergone TDS analysis, which has been analysed to identify the properties of extrinsic traps induced by the damage and to determine how they evolve with damage and annealing temperature. A parametric study investigated the impact of the damage rate and temperature on tritium inventories in tungsten. Tritium transport simulations have been performed with FESTIM considering a 1D model of a 2 mm sample of tungsten with damage rates and temperatures varying from 0– 10 2 dpa/fpy and 600–1300 K, respectively. The results show that after 24 h simultaneous exposure to neutron damage at 10 2 dpa/FPY and tritium implantation at 700 K, tritium inventories can increase by up to four orders of magnitude when damaged at a rate of 10 2 dpa/FPY compared to undamaged, defect-free tungsten, increasing further to five orders of magnitude after one full power year. The time taken to reach retention saturation shows the need for kinetic models of trapping properties on time scales relevant to reactor operation. The trap-creation model parameterisation procedure can be used to investigate neutron damage effects on other fusion-relevant materials such as EUROFER, Inconel and more.

“…, I (t − m∆t) , t, ∆t, m, Popt) . (7) In this way the model acts as a state observer which is constrained by the available measurements. The observed state variables can then be used in a traditional control scheme by computing the control error:…”

Section: Use Of Models In Control and Estimationmentioning

confidence: 99%

“…The plasma control system must be able to guide and stabilise this system using the limited external actuators. Four fifth of the power produced in the fusion reaction will leave the plasma in the form of 14 MeV neutrons and these will be absorbed in the breeding blankets surrounding the plasma, producing the tritium required for continuous operation [7]. The remaining fifth of the fusion power plus the external power injected into the plasma, will leave the plasma impacting the plasma facing components.…”

Section: Introductionmentioning

confidence: 99%

Plasma control for the step prototype power plant

Lennholm,

Aleiferis,

Bakes

et al. 2024

In 2019 the UK launched the STEP programme to design and build a prototype electricity producing nuclear fusion power plant, aiming to start operation around 2040. The plant should lay the foundation for the development of commercial nuclear fusion power plants. The design is based on the spherical tokamak principle, which opens a route to high pressure, steady state, operation. While facilitating steady state operation, the spherical design introduces some specific plasma control challenges: i) All plasma current during the burn phase should to be generated through non-inductively means, dominated by bootstrap current. This leads to operation at high normalised plasma pressure β_"N" with high plasma elongation, which in turn imposes effective active stabilisation of the vertical plasma position. ii) The tight aspect ratio means very limited space for a central solenoid, imposing that even the current ramp up must be non-inductively generated. iii) The compact design leads to extreme heat loads on plasma facing components. A double null design has been chosen to spread this load, putting strict demands on the control of the unstable vertical plasma position. iv) The heat pulses associated with unmitigated ELMs are unlikely to be unacceptable imposing ELM free operation or active ELM control. v) To reduce and spread heat loads, core and divertor radiation and momentum loss has to be controlled, aiming to operate with simultaneously detached upper and lower divertors. vi) High pressure operation is likely to require active resistive wall mode stabilisation. vii) The conductivity distribution in structures near the plasma must be carefully selected to reduce the growth rates for the vertical instability and the resistive wall mode without damping the penetration of the of magnetic fields from active control coils too much. This article describes the initial work carried out to develop a STEP plasma control system.