Impurity enrichment studies with induced scrape-off layer flow on DIII-D

Wade, M. R.; Hogan, J.; Allen, S. L.; Brooks, N.H.; Hill, D. N.; Maingi, R.; Schaffer, M. J.; Watkins, J.G.; Whyte, D.G.; Wood, R. D.; West, W.P.

doi:10.1088/0029-5515/38/12/309

Cited by 56 publications

(67 citation statements)

References 26 publications

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“…Better closure of divertor mechanical leaks enhances compression of deuterium, helium [232,240] and argon [241] but appears to have no effect on helium or argon enrichment. Induced scrapeoff layer flow by the 'puff and pump' technique did not significantly alter the enrichment of helium [242,212,240] but enhanced the neon and argon enrichment in DIII-D [242] and JT-60U [243], although not in ASDEX-U [212] or JET [240]. The reasons for this discrepancy…”

Section: Helium Exhaust and Noble Gas Impurity Enrichmentmentioning

confidence: 88%

“…Neon and argon, are ionised much closer to the divertor target and, therefore, experience the frictional drag force as ions, driving them back toward the target. As a consequence, the enrichment (and compression) increases with increasing noble gas mass and it is usually larger than unity for the heavier species in all divertor conditions [242,244,240]. The enrichment of neon and argon increases with increasing density up to detachment [242,244,240] after which it drops.…”

Section: Helium Exhaust and Noble Gas Impurity Enrichmentmentioning

confidence: 96%

“…As a consequence, the enrichment (and compression) increases with increasing noble gas mass and it is usually larger than unity for the heavier species in all divertor conditions [242,244,240]. The enrichment of neon and argon increases with increasing density up to detachment [242,244,240] after which it drops. However, such an effect is less likely to occur in next step devices because the ratio of λ IONIS to divertor size will be much smaller than in present experiments for all regimes (including detached divertor plasmas).…”

Section: Helium Exhaust and Noble Gas Impurity Enrichmentmentioning

confidence: 96%

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Chapter 4: Power and particle control

Divertor¹,

Database²,

Editors³

1999

Nucl. Fusion

279

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Abstract.Progress, since the ITER Physics Basis publication, in understanding the processes that will determine the properties of the plasma edge and its interaction with material elements in ITER is described. Experimental areas where significant progress has taken place are : energy transport in the SOL in particular of the anomalous transport scaling, particle transport in the SOL that plays a major role in the interaction of diverted plasmas with the main chamber material elements, ELM energy deposition on material elements and the transport mechanism for the ELM energy from the main plasma to the plasma facing components, the physics of plasma detachment and neutral dynamics including the edge density profile structure and the control of plasma particle content and He removal, the erosion of low and high Z materials in fusion devices, their transport to the core plasma and their migration at the plasma edge including the formation of mixed materials, the processes determining the size and location of the retention of tritium in fusion devices and methods to remove it and the processes determining the efficiency of the various fuelling methods as well as their development towards the ITER requirements. This experimental progress has been accompanied by the development of modelling tools for the physical processes at the edge plasma and plasma-materials interaction and the further validation of these models by comparing their predictions with the new experimental results. Progress in the modelling development and validation has been mostly concentrated in the following areas : refinement of the predictions for ITER with plasma edge modelling codes by inclusion of detailed geometrical features of the divertor and the introduction of physical effects, which can play a 2 major role in determining the divertor parameters at the divertor for ITER conditions such as hydrogen radiation transport and neutral-neutral collisions, modelling of the ion orbits at the plasma edge, which can play a role in determining power deposition at the divertor target, models for plasma-materials and plasma dynamics interaction during ELMs and disruptions, models for the transport of impurities at the plasma edge to describe the core contamination by impurities and the migration of eroded materials at the edge plasma and its associated tritium retention and models for the turbulent processes that determine the anomalous transport of energy and particles across the SOL. The implications for the expected performance of the reference regimes in ITER, the operation of the ITER device and the lifetime of the plasma facing materials are discussed. Introduction.This chapter outlines the significant progress achieved since the ITER Physics Basis in understanding basic scrape-off layer (SOL) and divertor processes in a tokamak. The interaction of plasma with first-wall surfaces will have considerable impact on the performance of fusion plasmas, the lifetime of plasma facing components, and the retention of tritium in next step Burning Plasma E...

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Section: Helium Exhaust and Noble Gas Impurity Enrichmentmentioning

confidence: 88%

Section: Helium Exhaust and Noble Gas Impurity Enrichmentmentioning

confidence: 96%

Section: Helium Exhaust and Noble Gas Impurity Enrichmentmentioning

confidence: 96%

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Chapter 4: Power and particle control

Divertor¹,

Database²,

Editors³

1999

Nucl. Fusion

279

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“…For this "radiating divertor" concept to be practical, however, the confinement and stability of the plasma cannot be compromised by excessive leakage of the seeded impurities into the core plasma. One proposed way of reducing impurity influx is to enhance the directed scrape-off layer (SOL) flow of deuterium ions toward the divertor [1][2][3][4][5].…”

Section: Compatibility Of the Radiating Divertormentioning

confidence: 99%

Compatibility of the radiating divertor with high performance plasmas in DIII-D

Pétrie

Wade

Brooks

et al. 2007

Journal of Nuclear Materials

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“…ELMs allow sustainment of steadystate phases with exhaust of impurities such as helium ash [5][6][7][8]. ELMy H-mode experiments performed in many divertor tokamaks have also demonstrated favorable energy confinement.…”

Section: Introductionmentioning

confidence: 99%

Pedestal Characteristics of H-Mode Plasmas in JT-60U and ASDEX Upgrade

Urano¹,

Kamada²,

Takizuka³

et al. 2005

J. Plasma Fusion Res.

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The role of the pedestal structure in ELMy H-mode plasmas for the core energy confinement and for the ELM energy losses were investigated in two tokamak-type devices, JT-60U and ASDEX Upgrade. The confinement degradation seen at higher densities is attributed to the reduction of the pedestal temperature limited by the ELM activities and the stiffness of the temperature profiles. In high triangularity or impurity seeded H-modes, in which higher energy confinement is generally achieved, a higher pedestal temperature is obtained by improving the edge MHD stability or the density profile peaking, respectively. The upper bound of the ELM energy loss is characterized by the pedestal energy. The ELM energy loss can become smaller at fixed pedestal energy when the pedestal collisionality is raised. Raising the pedestal collisionality also enhances the inter-ELM perpendicular transport loss and reduces the ELM loss power fraction. In ASDEX Upgrade, the continuous pellet injection is shown to effectively mitigate ELM losses while preserving the core confinement quality. In JT-60U, the operation regime of grassy ELM is investigated and shown to achieve highly integrated performance of high energy confinement with small ELMs in the low collisionality regime.

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Impurity enrichment studies with induced scrape-off layer flow on DIII-D

Cited by 56 publications

References 26 publications

Chapter 4: Power and particle control

Chapter 4: Power and particle control

Compatibility of the radiating divertor with high performance plasmas in DIII-D

Pedestal Characteristics of H-Mode Plasmas in JT-60U and ASDEX Upgrade

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