Hollow pellet injection for magnetic fusion

Wang, ‪Zhehui; Hoffbauer, Mark A.; Hollmann, E. M.; Sun, Zhuo; Wang, Y. M.; Eidietis, N. W.; Hu, Jiansheng; Maingi, R.; Ménard, J.; Xu, X. Q.

doi:10.1088/1741-4326/ab19eb

Cited by 4 publications

(4 citation statements)

References 41 publications

(56 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Therefore, the development of new detachment feedback controllers in high β P scenario is needed. In the DIII-D 2018 campaign, the feedback control of radiation was utilized and demonstrated in the high β P scenario [10,16], which accessed partial divertor detachment successfully in LSN configuration. In 2019, a more precise controller utilizing the divertor Langmuir probe measured particle flux (J sat ) to characterize the degree of detachment (DoD) was successfully developed and demonstrated in the high β P scenario, similar to the jointly developed J sat controller in the EAST tokamak [14] and JET [8].…”

Section: Detachment Feedback Controller Development In Diii-d High β ...mentioning

confidence: 99%

“…In Alcator C-Mod, realtime control of heat flux was obtained using surface thermocouple diagnostic [9], with T et,div at the strike point reduced from ∼20 eV to below 10 eV in N 2 seeding discharges. Previous DIII-D divertor radiation power feedback control with N 2 seeding in the high β P scenario was performed without accessing detachment [10], in addition to detachment feedback control via divertor Thomson scattering measured T et, div controller in L-mode [11] and H-mode [12] which accessed marginal detachment between ELMs. In the EAST superconducting tokamak, total plasma radiation feedback control was achieved with the divertor plasma still being attached [13], while H-mode detachment was achieved via the divertor particle flux controller [10,14] with neon seeding mixed with deuterium.…”

Section: Introductionmentioning

confidence: 99%

“…Previous DIII-D divertor radiation power feedback control with N 2 seeding in the high β P scenario was performed without accessing detachment [10], in addition to detachment feedback control via divertor Thomson scattering measured T et, div controller in L-mode [11] and H-mode [12] which accessed marginal detachment between ELMs. In the EAST superconducting tokamak, total plasma radiation feedback control was achieved with the divertor plasma still being attached [13], while H-mode detachment was achieved via the divertor particle flux controller [10,14] with neon seeding mixed with deuterium. Very recently in TCV, C-III emission front was successfully feedback controlled, while no clear signature of detachment was observed [15].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Achievements of actively controlled divertor detachment compatible with sustained high confinement core in DIII-D and EAST

Wang

Eldon

et al. 2022

Nucl. Fusion

View full text Add to dashboard Cite

The compatibility of efficient divertor detachment with high-performance core plasma is vital to the development of magnetically controlled fusion energy. The joint research on the EAST and DIII-D tokamaks demonstrates successful integration of divertor detachment with excellent core plasma confinement quality, a milestone towards solving the critical Plasma-wall-interaction (PWI) issue and core-edge integration for ITER and future reactors. In EAST, actively controlled partial detachment with Tet,div ~ 5 eV around the strike point and H98 > 1 in different H-mode scenarios including the high βP H-mode scenario have been achieved with ITER-like tungsten divertor, by optimizing the detachment access condition and performing detailed experiments for core-edge integration. For active long pulse detachment feedback control, a 30s H-mode operation with detachment-control duration being 25s has been successfully achieved in EAST. DIII-D has achieved actively controlled fully detached divertor with low plasma electron temperature (Tet,div ≤ 5 eV across the entire divertor target) and low particle flux (degree of detachment, DoD >3), simultaneously with very high core performance (βN ~3, βP >2 and H98~1.5) in the high βP scenario being developed for ITER and future reactors. The high-βP high confinement scenario is characterized by an internal transport barrier (ITB) at large radius and a weak edge transport barrier (ETB, or pedestal), which are synergistically self-organized. Both the high-βP scenario and impurity seeding facilitate divertor detachment. The detachment access leads to the reduction of ETB, which facilitates the development of an even stronger ITB at large radius in the high βP scenario. Thus, this strong large radius ITB enables the core confinement improvement during detachment. These significant joint DIII-D and EAST advances on the compatibility of high confinement core and detached divertor show a great potential for achieving a high-performance core plasma suitable for long pulse operation of fusion reactors with controllable steady-state PWIs.

show abstract

Section: Detachment Feedback Controller Development In Diii-d High β ...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Achievements of actively controlled divertor detachment compatible with sustained high confinement core in DIII-D and EAST

Wang

Eldon

et al. 2022

Nucl. Fusion

View full text Add to dashboard Cite

show abstract

“…EAST has developed ITER-like heating systems, active impurity and recycling control systems, an active water-cooled ITER-like tungsten (W) divertor, various ELM mitigation technologies, and modern diagnostics. The combination of these capabilities resulted in H-mode discharges with durations over 100 s [50,51]. To achieve long pulse recycling and impurity control, Li wall conditioning was employed, via a combination of overnight evaporation and periodic use of real-time Li aerosol or granule injection [51,52].…”

Section: East Descriptionmentioning

confidence: 99%

Type-I ELM mitigation by continuous lithium granule gravitational injection into the upper tungsten divertor in EAST

et al. 2021

Self Cite

View full text Add to dashboard Cite

Large edge-localized modes (ELMs) were mitigated by gravitational injection of lithium granules into the upper X-point region of the experimental advanced superconducting tokamak (EAST) device with tungsten plasma-facing components. The maximum ELM size was reduced by ∼70% in high β N H-mode plasmas. Large ELM stabilization was sustained for up to about 40 energy confinement times, with constant core radiated power and no evidence of high-Z or low-Z impurity accumulation. The lithium granules injection reduced the edge plasma pedestal density and temperature and their gradients, due to increased edge radiation and reduced recycling from the plasma-facing components. Ideal stability calculations using the ELITE code indicate that the stabilization of large ELMs correlates with improved stability of intermediate-n peeling-ballooning modes, due to reduced edge current resulting from the profile changes. The pedestal pressure reduction was partially offset by a core density increase, which resulted in a modest ∼7% drop in core stored energy and normalized energy confinement time. We surmise that the remnant small ELMs are triggered by the penetration of multiple Li granules just past the separatrix, similar to small ELMs triggered by deuterium pellet Futatani et al (2014 Nucl. Fusion 54 073008). This study extends previous ELM elimination with Li powder injection Maingi et al (2018 Nucl. Fusion 58 024003) in EAST because (1) use of small, dust-like powder and the related potential health hazards were eliminated, and (2) use of macroscopic granules should be more applicable to future devices, due to deeper penetration than dust particles, e.g. inside the separatrix with velocities ∼10 m s−1 in EAST.

show abstract

Simulation of lithium transport using the BOUT++ framework

Wang

et al. 2021

Computer Physics Communications

View full text Add to dashboard Cite

Hollow pellet injection for magnetic fusion

Cited by 4 publications

References 41 publications

Achievements of actively controlled divertor detachment compatible with sustained high confinement core in DIII-D and EAST

Achievements of actively controlled divertor detachment compatible with sustained high confinement core in DIII-D and EAST

Type-I ELM mitigation by continuous lithium granule gravitational injection into the upper tungsten divertor in EAST

Simulation of lithium transport using the BOUT++ framework

Contact Info

Product

Resources

About