The influence of full drifts on density shoulder formation at the midplane by numerical modeling

Zhao, Xuele; Sang, Chaofeng; Senichenkov, I.; Wang, Yilin; Zhang, Yanjie; Zhang, Chen; Rozhansky, V.; Wang, Dezhen

doi:10.1088/1741-4326/ac9b77

Cited by 2 publications

(3 citation statements)

References 62 publications

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“…Since the numerical convergence has been improved in SOLPS-ITER, the full drifts can now be simulated [29]. In this study, a DIII-D-like closed divertor geometry [3,30] is selected and the location of the pump is labeled in figure 1. This study is a continuation of our previous works [3,13,15].…”

Section: Simulation Modelmentioning

confidence: 99%

“…Here, the poloidal direction is along the flux surfaces, while the radial direction is perpendicular to the flux surfaces. The neutral particles (D, C and [30,32,33]. Atomic and molecular processes (charge-exchange, ionization, recombination, etc) are also included in the simulation.…”

Section: Simulation Modelmentioning

confidence: 99%

“…The full drifts, including E × B drift, diamagnetic drift and related viscosity, are activated, and all current terms are enabled. The anomalous transport coefficients are the same as in [3,30]. The input power is set at P SOL = 3 MW at the core-edge interface (CEI).…”

Section: Simulation Modelmentioning

confidence: 99%

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The role of divertor pumping combined with full drifts in particle exhaust and divertor plasma

Zhao,

Sang,

Wang

et al. 2024

Nucl. Fusion

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The effect of drifts combined with pumping on particle exhaust is assessed using the SOLPS-ITER code package, considering full drifts. Both drifts and pumping speed S can affect particle exhaust. Drifts change the neutral density by influencing plasma flow and the resulting particle recycling. This leads to the accumulation of neutral particles either far away or close to the pump opening location. While the particle exhaust is enhanced as S raises. When the pump opening is positioned at the common flux region (CFR) of the outer divertor (referred to as Pump CFR/OD), particle exhaust is suppressed by drifts in forward Bt, while it is enhanced by drifts in reversed Bt, with fixed S. On the other hand, when the pump is situated in the private flux region (PFR) of the outer divertor (referred to as Pump PFR/OD), particle exhaust is enhanced by drifts in both reversed and forward Bt compared to the case without drifts. Moreover, the effective pumping in reversed Bt is stronger than in forward Bt. In the same Bt direction, Pump PFR/OD has a higher effective pumping than Pump CFR/OD. Increased S results in higher particle exhaust in all Bt direction and pump location cases. The plasma detachment is affected by drifts, S and pump opening location, respectively. For the specified Bt direction and pump opening location case, higher S suppresses plasma detachment. For an identical particle exhaust rate, stronger pumping capacity can promote plasma detachment. Therefore, Pump PFR/OD can more easily achieve outer divertor detachment than Pump CFR/OD in the same Bt direction. Overall, placing the pump at the PFR side of the outer divertor while running in reversed Bt is the best option from the divertor particle exhaust and plasma detachment point of view.

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Section: Simulation Modelmentioning

confidence: 99%

Section: Simulation Modelmentioning

confidence: 99%

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The role of divertor pumping combined with full drifts in particle exhaust and divertor plasma

Zhao,

Sang,

Wang

et al. 2024

Nucl. Fusion

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Simulation of tungsten impurity transport by DIVIMP under different divertor magnetic configurations on HL-3

ZHOU 周,

ZHANG 张,

SANG 桑

et al. 2024

Plasma Sci. Technol.

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Tungsten (W) accumulation in the core, depending on W generation and transport in the edge region, is a severe issue in fusion reactor. The divertor plasma parameters, such as heat flux to the target, can be effectively suppressed by changing the divertor magnetic configuration. Nevertheless, its impact on W core accumulation remains unclear. The HL-3 tokamak has advantage of operating with flexible divertor configurations, e.g. standard divertor (SD) and snowflake divertors (SFD). In this study, DIVIMP combined with SOLPS-ITER is applied to investigate the effects of divertor magnetic configurations (SD vs SFD) on W accumulation during neon injection in HL-3. It is found that W concentration in the core of SFD is significantly higher than that of SD with similar total W erosion flux. The reasons are: (1) W impurities in the core of SFD mainly originate from inner divertor, which has short leg, and the source is close to the divertor entrance and upstream separatrix. Furthermore, the SW0 is much stronger, especially near divertor entrance. (2) the region overlap of SW0 and F_(W,TOT) pointing to upstream promote W accumulation in the core. Moreover, influence of W source locations at inner target on W transport in the SFD is investigated. Tungsten impurity in the core is mainly contributed by target erosion at common flux region (CFR) away from strike point. This is attributed to that W source at this location enhances ionization source above the W ion stagnation point, which sequentially increases W penetration. Therefore, the suppression of far SOL inner target erosion can effectively prevent W impurities from accumulating in the core.

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The influence of full drifts on density shoulder formation at the midplane by numerical modeling

Cited by 2 publications

References 62 publications

The role of divertor pumping combined with full drifts in particle exhaust and divertor plasma

The role of divertor pumping combined with full drifts in particle exhaust and divertor plasma

Simulation of tungsten impurity transport by DIVIMP under different divertor magnetic configurations on HL-3

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