Power deposition behavior of high-density transient hydrogen plasma on tungsten in Magnum-PSI

Li, Y.; Morgan, T.W.; Berg-Stolp, J. van den; Genuit, J.W.; Temmerman, G. De; Hoefnagels, Jpm Johan; Dommelen, J.A.W. van; Verbeken, Kim; Geers, M.G.D.

doi:10.1088/1361-6587/ac0bc9

Cited by 4 publications

(7 citation statements)

References 46 publications

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“…Because of the low H 2 density and high electron density in Mangum-PSI, both of which inhibit H 2 + /H 3 + formation, the ion population is predominantly H + [35,36]. This is consistent with the agreed heat fluxes from calorimetry and TS data [32]. The peak H + ion energy was ∼6 eV and the exposure time was ∼10 4 seconds.…”

Section: In Situ Diagnosticssupporting

confidence: 81%

“…At a surface temperature of 750 • C, a similar ΔT induced ∼0.6% von Mises plastic strain per cycle according to finite element calculation [31]. Table 2 summarizes the key loading parameters, in which the H + ion fluence was calculated with a collisionless sheath model using the measured TS data [32]. In the calculation, T e = T i was assumed as justified by coherent TS measurements [33,34].…”

Section: In Situ Diagnosticsmentioning

confidence: 99%

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Influence of porosity and blistering on the thermal fatigue behavior of tungsten

Li¹,

Vermeij²,

Hoefnagels³

et al. 2022

Nucl. Fusion

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Tungsten is the leading plasma-facing material (PFM) for nuclear fusion applications. It faces severe operating conditions, including intense hydrogen plasma exposure and high-cycle transient heat loading, which create various defects in tungsten. Additionally, defects have often already been introduced during manufacturing. Little is understood regarding the synergistic effect of such defects on the lifetime of tungsten so far. Here, we investigate the influence of porosity and blistering on the thermal fatigue behavior of tungsten. The pores resulted from powder metallurgy whereas the blistering was induced by hydrogen plasma exposure. Both conditions were subjected to transient heat loading by a high-power pulsed laser. The exposure was performed in the linear plasma generator Magnum-PSI, which closely mimics the expected particle and heat flux in the world’s largest fusion experiment, ITER. Both porosity and blistering degraded the fatigue resistance of tungsten. Pores tended to aggregate at high-angle grain boundaries (HAGBs) and assisted crack initiation therein, as revealed by focused ion beam (FIB) cross-sectioning and electron backscatter diffraction (EBSD) analysis. The blisters were characteristic of subsurface cavities, which were located at a depth close to the surface roughness induced by transient heat loading. The stress concentration at the tip of the cavities is considered to promote crack initiation. The results highlight the necessity of a ‘life cycle assessment’ of the tungsten PFM for nuclear fusion reactors.

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Section: In Situ Diagnosticssupporting

confidence: 81%

Section: In Situ Diagnosticsmentioning

confidence: 99%

Influence of porosity and blistering on the thermal fatigue behavior of tungsten

Li¹,

Vermeij²,

Hoefnagels³

et al. 2022

Nucl. Fusion

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“…The present experiments performed in the high p n cases seem to demonstrate heat pulse mitigation with a completely different mechanism from the present low p n cases and [14]. Recycled neutral particles have difficulty interacting with pulsed plasma because the collisions of recycled particles with background neutral particles are comparable to the collisions with pulsed ions in high p n cases, as discussed in section 4.1.2.…”

Section: Pulse Mitigation Under High Pn Conditionscontrasting

confidence: 39%

“…To discuss the mitigation mechanism of the pulse, a previous study on power deposition by transient plasma should be covered. A fast infrared camera coupled to a finite element analysis was used to acquire the heat flux deposited by the pulsed plasma inputs on the Magnum-PSI target in [14]. Clear energy loss was observed in the pulsed plasma with high n e and the possible interpretations are as follows: Owing to the enhanced recycling of particles in high n e cases, T e decreases due to ionization in front of the target.…”

Section: Pulse Mitigation Under Low Pn Conditionsmentioning

confidence: 99%

“…Such experiments are realized in the linear plasma device Magnum-PSI because of its high performance for steady-state plasma generation with a particle flux of 10 23 -10 25 m −2 s −1 and high-density pulsed plasma production [12,13]. The density dependence of the pulsed heat load was studied in Magnum-PSI [14], which indicated the saturation of the peak heat load into the target in a high-density regime. Localized enhancement of the ionization and charge exchange (CX) processes was implied to constitute the energy-loss mechanism.…”

Section: Introductionmentioning

confidence: 99%

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Reduction of pulsed particle load with dynamic pressure induced by transient recycled neutral flux

Hayashi¹,

Tanaka²,

Ohno³

et al. 2022

Plasma Phys. Control. Fusion

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From pulsed plasma experiments focusing on neutral pressure dependence, the impacts of a transition from a low to a high recycling target on the particle load were investigated and discussed in the linear plasma device, Magnum-PSI. Time traces of the target ion flux were mitigated in high neutral pressure cases because of a plasma-neutral interaction. On the other hand, in low neutral-pressure cases, the target ion flux indicated partial suppression in the last part of the pulse. The Langmuir probe, located 200 mm upstream from the target plate, did not exhibit such a suppression. Pulse suppression can be expected from the localized interaction between recycled neutral flux and pulsed plasma in front of the target. The mean-free paths of recycled neutral particles regarding the charge exchange with pulse ions and elastic scattering with background neutral particles were compared. Modeling using a fluid code coupled with a neutral transport code was performed, and it was concluded that dynamic pressure induced by the transient recycled neutral flux caused sufficient momentum loss to stagnate the pulsed plasma toward the target plate.

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Simulation of the impact of particle recycling on the plasma in MPS‐LD device based on the BOUT++ LPD module

Wang,

Sun,

Sang

et al. 2024

Contrib. Plasma Phys

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A linear plasma device (LPD) module has been developed under the BOUT++ framework to simulate plasma transport in the MPS‐LD. However, previously, the LPD module used a simplistic neutral particle model that only includes particle density and velocity, which prevents the full understanding of the plasma‐neutrals interactions. In this work, we further optimize the neutral model by using a more complete neutral fluid model containing the continuity equation, momentum equation, and energy equation. The reactions such as charge exchange, excitation, and radiation collisions are included. Since the neutral particle source is mainly provided by particle recycling from the target, a particle recycling model is employed, which includes both fast reflection and slow thermal release. The upgraded LPD module is applied to simulate the argon (Ar) discharge experiment of MPS‐LD, and the benchmark against experiment measurement and SOLPS‐ITER simulation results are presented. Good agreements are obtained, showing the validation of the upgraded module. After that, the impact of particle recycling on Ar plasma is investigated. It is found that a higher recycling coefficient (R) promotes the achievement of high‐density plasma at the target. The recycled Ar atoms change target plasma pressure as well as plasma‐neutral collisions, which both contribute to plasma momentum loss, thus promoting the rollover of ion flux to the target.

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Power deposition behavior of high-density transient hydrogen plasma on tungsten in Magnum-PSI

Cited by 4 publications

References 46 publications

Influence of porosity and blistering on the thermal fatigue behavior of tungsten

Influence of porosity and blistering on the thermal fatigue behavior of tungsten

Reduction of pulsed particle load with dynamic pressure induced by transient recycled neutral flux

Simulation of the impact of particle recycling on the plasma in MPS‐LD device based on the BOUT++ LPD module

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