Analysis of Avalanche Runaway Generation after Disruptions with Low-&lt;i&gt;Z &lt;/i&gt;and Noble Gas Species

Matsuyama, Akinobu; Yagi, M.

doi:10.1585/pfr.12.1403032

Cited by 10 publications

(13 citation statements)

References 59 publications

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“…In this study, the time evolution of the plasma parameters in the startup phase of JT-60SA is numerically investigated using the 0D simulation code INDEX-S. This 0D code was originally developed to study the plasma current quench and RE generation during disruptions [35]. For the present analyses, we have implemented the additional models outlined below.…”

Section: Plasma Breakdown Burn-through and Pwi Modelsmentioning

confidence: 99%

“…To date, RE generation during startup has long been studied [18,19,29], and different RE models have recently been incorporated into the 0D plasma burn-through codes, such as SCENPLINT/TRANSMAK [7,[30][31][32], STREAM [33], and DYON [34]. In a similar approach, the possibility of RE discharges occurring at JT-60SA is studied numerically using the RE generation model [35]. The simulation shows that startup REs are generated during the temperature rise immediately after the burn-through under relatively low-density conditions-depending on the prefill gas pressure and the recycling process.…”

Section: Introductionmentioning

confidence: 99%

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Modelling of ohmic startup and runaway electron formation in support of JT-60SA initial operation

Matsuyama¹,

Wakatsuki²,

Inoue³

et al. 2022

Nucl. Fusion

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The plasma startup with ITER-relevant sub-mPa neutral pressures in the JT-60SA superconducting tokamak is studied using a zero-dimensional (0D) power balance model for the plasma burn-through phase. In the ohmic startup scenario assumed here, the lower limit of the operational neutral pressure is determined by the condition for the Townsend avalanche at a high $E/p$ limit, whereas the upper limit depends on the available ohmic heating power for the burn-through with the base Power Supply (PS) of the superconducting coils, corresponding to 0.2-0.3 V/m. The operational conditions that lead to RE generation are evaluated to mitigate the risk of RE discharges. The simulation shows that startup REs are generated during the temperature rise immediately after the burn-through under relatively low-density conditions, and then the RE current value is gradually increased in balance with the RE loss processes on the timescale of $I_p$ ramp-up. Therefore, it is expected that REs can be avoided or mitigated if the electron density during the early build-up phase is tuned by a combination of prefill gas and additional fuelling. However, a startup with an excessive prefill gas will lose the margin of the density control, and a full RE discharge can be triggered when the plasma burn-through fails owing to a high concentration of impurities such as oxygen, if the operational point is marginal to the burn-through limit. The present modelling work implies that preparing the operation with sufficient margins against the failure of impurity burn-through is important for mitigating the risk of unintended plasma termination. Although the carbon wall environment may have a lower risk of RE generation, to alleviate the operational uncertainties of the new device, strategies for expanding the operational window are also discussed in support of JT-60SA initial operation.

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Section: Plasma Breakdown Burn-through and Pwi Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modelling of ohmic startup and runaway electron formation in support of JT-60SA initial operation

Matsuyama¹,

Wakatsuki²,

Inoue³

et al. 2022

Nucl. Fusion

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“…The experimental observations were investigated with numerical calculations performed to estimate RE energy dynamics using a simple 0-D code PREDICT [41,43,44]. The code employs the relativistic test particle equations that govern RE energy dynamics in momentum space, including collisional and synchrotron-radiation induced losses [44][45][46][47]. It also considers different RE-generation mechanisms such as the secondary avalanche and primary RE-generation mechanisms, namely Dreicer, hot-tail, tritium decay and Compton scattering (from γ-rays emitted from activated walls) [46].…”

Section: Evolution Of Re Maximum Energymentioning

confidence: 99%

“…It also considers different RE-generation mechanisms such as the secondary avalanche and primary RE-generation mechanisms, namely Dreicer, hot-tail, tritium decay and Compton scattering (from γ-rays emitted from activated walls) [46]. In the present simulation work, the following test particle equations utilized where the effect of impurities are taken into account considering collisions of REs with free and bound electrons and scattering from the full and partially-shielded nuclear charge [46,47]:…”

Section: Evolution Of Re Maximum Energymentioning

confidence: 99%

“…m e is the mass of an electron, ε 0 is the permittivity of free space. The parameters α e (γ)and Z coll (γ) are correctional factors that take into account the collisions of REs with free and bound electrons as well as scattering from full and partially-shielded nuclear charge as calculated and described in [47]. In these simulations, all temporal evolution of plasma parameters has been taken as an input and the only free parameter is a temporal evolution of injected argon atoms density profile.…”

Section: Evolution Of Re Maximum Energymentioning

confidence: 99%

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Study of runaway electron dynamics at the ASDEX Upgrade tokamak during impurity injection using fast hard x-ray spectrometry

et al. 2021

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To study the runaway electron (RE) dynamics during plasma discharge and develop scenarios for disruption mitigation, a hard x-ray (HXR) spectrometric system has been developed and commissioned at the ASDEX Upgrade tokamak (AUG). The diagnostic system consists of two high-performance spectrometers based on LaBr3(Ce) scintillation detectors supplied with advanced electronics and analysis algorithms. These spectrometers view the AUG tokamak chamber quasi-radially at the equatorial plane. The measurements were carried out in the RE beam generation regimes by injecting argon into a deuterium plasma. In the interaction of a developed RE beam with a heavy gas target, powerful bremsstrahlung flux is induced, reaching energy close to 20 MeV. The electron energy distributions were reconstructed from the measured HXR spectra by deconvolution methods. The experimentally obtained maximum RE energies at different discharge stages were compared with relativistic test particle simulations that include the effect of toroidal electric field, plasma collisional drag force, synchrotron deceleration force. It was observed that the electrons attain their maximum energies within 50-100 ms after the gas injection. It gradually decreases due to the drop in loop voltage, energy loss due to synchrotron radiation emission and collisions dissipation of energy with the background plasma. HXR measurements at the discharge with multiple deuterium pellet injections allowed observing the effects of plasma cooling and argon ion

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Development of plasma control schemes and plan of plasma physics studies in JT-60SA

Urano

2022

Rev. Mod. Plasma Phys.

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Analysis of Avalanche Runaway Generation after Disruptions with Low-<i>Z </i>and Noble Gas Species

Cited by 10 publications

References 59 publications

Modelling of ohmic startup and runaway electron formation in support of JT-60SA initial operation

Modelling of ohmic startup and runaway electron formation in support of JT-60SA initial operation

Study of runaway electron dynamics at the ASDEX Upgrade tokamak during impurity injection using fast hard x-ray spectrometry

Development of plasma control schemes and plan of plasma physics studies in JT-60SA

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