First results of the use of a continuously flowing lithium limiter in high performance discharges in the EAST device

Hu, Jiansheng; Zuo, Guizhong; Ren, Jin; Yang, Qian; Chen, Z.X.; Xu, Hongli; Zakharov, L.; Maingi, R.; Gentile, C.; Meng, X.C.; Sun, Zhonghua; Xu, Wenhai; Chen, Y.; Fan, Dongjie; Niu, Y.; Duan, Yanmin; Yang, Zhongshi; Zhao, Hengyu; Song, Yuntao; Zhang, X.D.; Wan, Baonian; Li, J.G.; Team, East

doi:10.1088/0029-5515/56/4/046011

Cited by 68 publications

(43 citation statements)

References 36 publications

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“…The CCD camera system is installed at the horizontal distance of R = 2.90 m, which is located at the toroidal angle ϕ = 270° as shown in figure 1. The CCD camera system viewing the opposite side of the LLL is a true color camera with 20 Hz frame [21], which can provide the distributions of edge plasma and impurity emissions as shown in the inset profile. The LiII (wavelength at 548.40 nm with green visible spectrum) emission distribution can be observed by the CCD camera system as shown in the inset figure.…”

Section: The Description Of the Emc3-eirene Codementioning

confidence: 99%

EMC3-EIRENE modelling of edge plasma and impurity emissions compared with the liquid lithium limiter experiment on EAST

et al. 2018

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Studies of edge plasma and impurity transport with the toroidally and poloidally localized liquid lithium limiter (LLL) on EAST have been performed by the three-dimensional (3D) edge transport code EMC3-EIRENE. The transport behavior of the Li1+ and Li2+ ions shows a non-axisymmetric distribution in the toroidal direction while an axisymmetric distribution is obtained for the Li3+ ions. The spatial structure of the charge state and excitation radiation patterns of lithium impurity can be understood by using field line tracing, which shows that the Li ions with different charge states exhibit different parallel transport behaviors. The 3D line-integrated LiII emission pattern simulated by EMC3-EIRENE shows a reasonable qualitative agreement with the experiment results measured by the CCD camera system on EAST. An unresolved issue in the LLL experiment is that the species emitting the strong visible spectrum observed around the edge plasma region cannot be distinguished by the current experimental diagnostics on EAST. The detailed numerical analysis of the carbon and deuterium emissions has been carried out to resolve this issue. The simulated deuterium emission pattern shows the same qualitative behavior as the experimental observation at the lower divertor region. The strong radiation experimentally observed at the upper divertor region is perhaps due to the mixing of the lithium and deuterium emissions.

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Section: The Description Of the Emc3-eirene Codementioning

confidence: 99%

EMC3-EIRENE modelling of edge plasma and impurity emissions compared with the liquid lithium limiter experiment on EAST

et al. 2018

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“…To date, most LM-PFC research efforts (CDX-U [8], FLiLi [9], etc) have operated with small amounts of lithium (~1-2 (kg)) so it is possible that even modest levels of impurity could cause noticeable changes to flow and massbalance of the lithium [8,9,68]. Reactor-scale systems will require drastically larger lithium inventories and flow rates of approximately 1.2 (kg s −1 ) per 1 (MWTh), as shown by equation (21) [18].…”

Section: Conservation Of Massmentioning

confidence: 99%

“…Furthermore, several experiments have already shown that using lithium-PFC's on portions of a tokamak interior can greatly improve plasma performance by reducing particle recycling, increasing energy confinement, and suppressing impurity emissions [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Demonstrating electromagnetic control of free-surface, liquid-metal flows relevant to fusion reactors

et al. 2017

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Plasma-facing components (PFC's) made from solid materials may not be able to withstand the large heat and particle fluxes that will be produced within next-generation fusion reactors. To address the shortcomings of solid PFC's, a variety of liquid-metal (LM) PFC concepts have been proposed. Many of the suggested LM-PFC designs rely on electromagnetic restraint (Lorentz force) to keep free-surface, liquid-metal flows adhered to the interior surfaces of a fusion reactor. However, there is very little, if any, experimental data demonstrating that freesurface, LM-PFC's can actually be electromagnetically controlled. Therefore, in this study, electrical currents were injected into a free-surface liquid-metal that was flowing through a uniform magnetic field. The resultant Lorentz force generated within the liquid-metal affected the velocity and depth of the flow in a controllable manner that closely matched theoretical predictions. These results show the promise of electromagnetic control for LM-PFC's and suggest that electromagnetic control could be further developed to adjust liquid-metal nozzle output, prevent splashing within a tokamak, and alter heat transfer properties for a wide-range of liquid-metal systems.

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“…For example, in FTU, T-11M and CDX-U devices, plasma discharges with lower impurity control and higher confinement were achieved by using LLL [9][10][11][12][13][14]. Some promising results were also achieved in HT-7 and EAST by using a LLL [7,[15][16][17][18][19][20][21][22]. It was found that the H recycling was reduced by 20-30%, the particle confinement time increased by a factor of 2, the impurity emission intensity was decreased by about 10-20% and the energy confinement time was increased by 20%.…”

Section: Introductionmentioning

confidence: 99%

“…As mentioned above, the corrosion behaviors of structural materials in liquid Li depend seriously on the experiment conditions. Several LLLs on HT-7 [16][17][18][19][20] and EAST [20][21][22] have been performed since 2009. Two kinds of static liquid lithium limiters with free surface and capillary-pore system (CPS) configuration were successively utilized in HT-7 in 2009 and 2011 with pressure less than 4×10 -5 Pa.…”

Section: Introductionmentioning

confidence: 99%

Study of the corrosion behaviors of 304 austenite stainless steel specimens exposed to static liquid lithium at 600 K

Meng

Zuo

Ren

et al. 2016

Journal of Nuclear Materials

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Investigation of corrosion behavior of stainless steel served as one kind of structure materials exposed to liquid lithium (Li) is one of the keys to apply liquid Li as potential plasma facing materials (PFM) or blanket coolant in the fusion device.Corrosion experiments of 304 austenite stainless steel (304SS) were carried out in static liquid Li at 600 K and up to1584 hours at high vacuum with pressure less than 4×10 -4 Pa. After exposure to liquid Li, it was found that the weight of 304SS slightly decreased with weight loss rate of 5.7×10 -4 g/m 2 /h and surface hardness increased by about 50HV. Lots of spinel-like grains and holes were observed on the surface of specimens measured by SEM. By further EDS, XRD and metallographic analyzing, it was confirmed that the main compositions of spinel-like grains were M 23 C 6 carbides, and 304SS produced a non-uniform corrosion behavior by preferential grain boundary attack, possibly due to the easy formation of M 23 C 6 carbides and/or formation of Li

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First results of the use of a continuously flowing lithium limiter in high performance discharges in the EAST device

Cited by 68 publications

References 36 publications

EMC3-EIRENE modelling of edge plasma and impurity emissions compared with the liquid lithium limiter experiment on EAST

EMC3-EIRENE modelling of edge plasma and impurity emissions compared with the liquid lithium limiter experiment on EAST

Demonstrating electromagnetic control of free-surface, liquid-metal flows relevant to fusion reactors

Study of the corrosion behaviors of 304 austenite stainless steel specimens exposed to static liquid lithium at 600 K

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