Your search keyword '"Zuo, G Z"' showing total 21 results

1. I-mode Plasma Confinement Improvement by Real-time Lithium Injection and its Classification on EAST Tokamak

Author

Zhong, X. M., Zou, X. L., Liu, A. D., Song, Y. T., Zhuang, G., Liu, H. Q., Xu, L. Q., Li, E. Z., Zhang, B., Zuo, G. Z., Wang, Z., Zhou, C., Zhang, J., Shi, W. X., Gao, L. T., Wang, S. F., Gao, W., Jia, T. Q., Zang, Q., Zhao, H. L., Wang, M., Xu, H. D., Wang, X. J., Gao, X., Lin, X. D., Li, J. G., Group, EAST I-mode Working, and Team, EAST

Subjects

Physics - Plasma Physics

Abstract

I-mode is a promising regime for future fusion reactors due to the high energy confinement and the moderate particle confinement. However, the effect of lithium, which has been widely applied for particle recycling and impurity control, on I-mode plasma is still unclear. Recently, experiments of real-time lithium powder injection on I-mode plasma have been carried out in EAST Tokamak. It was found that the confinement performance of the I-mode can be improved by the lithium powder injection, which can strongly reduce electron turbulence (ET) and then trigger ion turbulence (IT). Four different regimes of I-mode have been identified in EAST. The Type I I-mode plasma is characterized by the weakly coherent mode (WCM) and the geodesic-acoustic mode (GAM). The Type II I-mode is featured as the WCM and the edge temperature ring oscillation (ETRO). The Type III I-mode corresponds to the plasma with the co-existence of ETRO, GAM, and WCM. The Type IV I-mode denotes the plasma with only WCM but without ETRO and GAM. It has been observed that WCM and ETRO are increased with lithium powder injection due to the reduction of ion and electron turbulence, and the enhancement of the pedestal electron temperature gradient. EAST experiments demonstrate that lithium powder injection is an effective tool for real-time control and confinement improvement of I-mode plasma.

Published

2024

2. A review of lithium application for the plasma-facing material in EAST Tokamak

Author

Hu, J. S., Li, L., Zuo, G. Z., Sun, Z., Xu, W., Meng, X. C., Li, C. L., Tang, Z. L., and Sun, J. Z.

Published

2023

3. Evolution of hydrogen isotopes retention behavior of in-situ boronization films in EAST

Author

Puyang, Shouan, primary, Xu, Yu-Ping, additional, Guan, Y.H., additional, Yang, Zhongshi, additional, Ding, Fang, additional, Zhou, Hai-Shan, additional, Zuo, G Z, additional, Hu, J S, additional, and Luo, Guang-Nan, additional

Published

2024

4. Experimental research of ECW pre-ionization and assisted startup in EAST

Author

Chen, Runze, primary, Liu, Wenbin, additional, Qian, Jinping, additional, Zhang, Bin, additional, Sun, Hongjuan, additional, Luo, Zhengping, additional, Yu, Yaowei, additional, Gao, Wei, additional, Li, Miaohui, additional, Xu, Handong, additional, Wang, Mao, additional, Zuo, G Z, additional, Zhang, Ling, additional, Zhou, Ruijie, additional, Jia, Tianqi, additional, Li, Pan, additional, Wang, Wei, additional, He, Yifan, additional, Wang, Zuhao, additional, Tao, Ye, additional, Hu, Yunchan, additional, Guan, Zhongfang, additional, Lu, Wenyi, additional, Guo, YuTong, additional, and Gong, Xianzu, additional

Published

2024

5. Safety factor diagnostic for tokamak core plasma from three-dimensional reconstruction of pellet ablation trail

Author

Liang, Chen, primary, Liu, Zhuang, additional, Yuan, J. S., additional, Li, Yichao, additional, Gu, Yongqi, additional, Huang, Dong, additional, Lu, Shaoyu, additional, Zuo, G. Z., additional, Hu, J. S., additional, and Feng, Yan, additional

Published

2024

6. Progress of Divertor Heat and Particle Flux Control in EAST for Advanced Steady-State Operation in the Last 10 Years

Author

Wang, L., Xu, G. S., Hu, J. S., Li, K. D., Yuan, Q. P., Liu, J. B., Ding, F., Yu, Y. W., Luo, Z. P., Xu, J. C., Meng, L. Y., Wu, K., Zhang, B., Chen, M. W., Deng, G. Z., Liu, X. J., Yang, Z. S., Liu, X., Liu, S. C., Ding, R., Zuo, G. Z., Sun, Z., Wu, J. H., Cao, B., Zhang, Y., Duan, Y. M., Zhang, L., Qian, X. Y., Li, A., Chen, L., Jia, M. N., Si, H., Xia, T. Y., Sun, Y. W., Chen, Y. P., Li, Q., Luo, G. N., Yao, D. M., Xiao, B. J., Gong, X. Z., Zhang, X. D., Wan, B. N., Wang, H. Q., Guo, H. Y., Eldon, D., Garofalo, A. M., Liang, Y., Xu, S., Sang, C. F., Wang, D. Z., Dai, S. Y., Sun, J. Z., Ding, H. B., Maingi, R., Gan, K. F., Zou, X. L., and Du, H. L.

Published

2021

7. Deuterium recycling and wall retention characteristics during boron powder injection in EAST

Author

Zuo, G Z, primary, Wang, Z., additional, Sun, Z, additional, Xu, W, additional, Zhou, Z.T., additional, Guan, Y.H., additional, Huang, M, additional, Maingi, R, additional, and Hu, J S, additional

Published

2023

8. Advances in the long-pulse steady-state high beta H-mode scenario with active controls of divertor heat and particle fluxes in EAST

Author

Wan, B. N., Gong, X. Z., Liang, Y., Xiang, N., Xu, G. S., Sun, Y., Wang, L., Qian, J. P., Liu, H. Q., Zhang, B., Xia, T. Y., Huang, J., Ding, R., Zhang, T., Zuo, G. Z., Sun, Z., Zeng, L., Zhang, X. J., Zang, Q., Lyu, B., Garofalo, A. M., Li, G. Q., Li, K. D., Yang, Q. Q., Wan, B. N., Gong, X. Z., Liang, Y., Xiang, N., Xu, G. S., Sun, Y., Wang, L., Qian, J. P., Liu, H. Q., Zhang, B., Xia, T. Y., Huang, J., Ding, R., Zhang, T., Zuo, G. Z., Sun, Z., Zeng, L., Zhang, X. J., Zang, Q., Lyu, B., Garofalo, A. M., Li, G. Q., Li, K. D., and Yang, Q. Q.

Published

2022

9. Comparison of active impurity control between lithium and boron powder real-time injection in EAST

Author

Xu, W, primary, Hu, J S, additional, Sun, Z, additional, Maingi, R, additional, Zuo, G Z, additional, Qian, Y Z, additional, Li, C L, additional, Zhang, L, additional, Meng, X C, additional, Huang, M, additional, Gao, W, additional, Duan, Y M, additional, Tang, Z L, additional, Yuan, J S, additional, and Zhang, D H, additional

Published

2021

10. Deuterium retention characteristics in Li film by coating and during flowing liquid Li limiter operation in experimental advanced superconducting tokamak

Author

Li, C L, primary, Zuo, G Z, additional, Maingi, R, additional, Cao, Bin, additional, Xu, W, additional, Meng, X C, additional, Sun, Z, additional, Huang, M, additional, Tang, Z L, additional, Zhang, D H, additional, Qian, Y Z, additional, Andruczyk, D, additional, Tritz, K, additional, and Hu, J S, additional

Published

2020

11. Effect of lithium coating on long pulse high performance plasma discharges in EAST

Author

Xu, W, primary, Hu, J S, additional, Sun, Z, additional, Maingi, R, additional, Zhang, L, additional, Yu, Y W, additional, Li, C L, additional, Zuo, G Z, additional, Qian, Y Z, additional, Huang, M, additional, Meng, X C, additional, Gao, W, additional, Duan, Y M, additional, Chen, Y J, additional, Wang, K, additional, Lin, X D, additional, and Gao, X, additional

Published

2020

12. Simulation of supersonic molecular beam injection fueling into H-mode plasmas on EAST using BOUT++

Author

Qian, Y. Z., primary, Xia, T. Y., additional, Huang, Y. Q., additional, Sun, Z., additional, Zuo, G. Z., additional, Xu, W., additional, Meng, X. C., additional, Huang, M., additional, Li, C. L., additional, Cao, B., additional, Wang, Y. M., additional, Zhang, T., additional, Ye, K. X., additional, Wang, Y. F., additional, Zang, Q., additional, Li, Y. Y., additional, and Hu, J. S., additional

Published

2020

13. Improvement on the plasma performances via application of flowing lithium limiters in EAST tokamak

Author

Zuo, G Z, primary, Hu, J S, additional, Maingi, R, additional, Li, C L, additional, Meng, X C, additional, Sun, Z, additional, Huang, M, additional, Xu, W, additional, Qian, Y Z, additional, Andruczyk, D, additional, Tritz, K, additional, Gong, X Z, additional, and Li, J G, additional

Published

2020

14. Investigation of edge impurity transport and divertor fluxes by toroidally localized lithium injection on EAST with EMC3-EIRENE

Author

Xie, T, primary, Dai, S Y, additional, Sun, Z, additional, Zuo, G Z, additional, Hu, J S, additional, Feng, Y, additional, and Wang, D Z, additional

Published

2019

15. Deuterium retention characteristics in Li film by coating and during flowing liquid Li limiter operation in experimental advanced superconducting tokamak.

Author

Li, C L, Zuo, G Z, Maingi, R, Cao, Bin, Xu, W, Meng, X C, Sun, Z, Huang, M, Tang, Z L, Zhang, D H, Qian, Y Z, Andruczyk, D, Tritz, K, and Hu, J S

Subjects

*DEUTERIUM, *FUSION reactor divertors, *PLASMA flow, *SURFACE coatings, *LIQUIDS, *PLASMA confinement, *HIGH temperatures

Abstract

Lithium (Li) is a promising low-Z material for particle recycling and impurity control to improve plasma performance in fusion devices. In the experimental advanced superconducting tokamak (EAST), Li coating has become a routine method for wall conditioning, and a flowing liquid Li (FLiLi) limiter has been successfully tested several times. Deuterium retention characteristics in the Li film coated on the international thermonuclear experimental reactor-like tungsten divertor and FLiLi during plasma discharges, which is important for the utilization of Li in future fusion devices, were investigated in EAST. It is found that the absorption of the fuel particles by Li coatings decreases gradually, and recycling gradually increases over a series of discharges. The maximum net amount of deuterium retained reached ∼0.8 g, corresponding to 12% deuterium in the Li. This corresponds to a whole day's worth of shots with a total of 87 plasma discharges and a total of ∼640s plasma time after 11.75 g Li was deposited. Compared to the Li coating, it is shown that FLiLi continuously traps fuel particles and achieves a higher deuterium retention ratio over both the short- and long-term, leading to lower recycling. Meanwhile, it is also observed that the fuel particle retention ratio increases when FLiLi is closer to the plasma. This result is likely due to higher plasma heating power and limiter temperature, which cause an increased Li efflux from FLiLi due to a higher limiter temperature, which then redeposits on the other plasma-facing surfaces and increases fuel particle absorption. It is estimated that ⩾80% of the retained D particles are captured by the continual renewal of the Li redeposition film during the FLiLi operation. This investigation would also be useful for D/T retention in future fusion devices if Li is used as a plasma-facing component. [ABSTRACT FROM AUTHOR]

Published

2021

16. ELM Suppression by Boron Powder Injection and Comparison with Lithium Powder Injection on EAST.

Author

Maingi, R., Hu, J. S., Sun, Z., Diallo, A., Tritz, K., Qian, Y. Z., Xu, W., Zuo, G. Z., Li, C. L., Huang, M., Ye, Y., Bortolon, A., Gilson, E. P., Lunsford, R., Mansfield, D. K., Nagy, A., Qian, J. P., and Gong, X. Z.

Abstract

Type I edge-localized modes (ELMs) in the Experimental Advanced Superconducting Tokamak (EAST) were completely suppressed via boron powder injection into the X-point region of an upper-single null configuration over a wide range of operating conditions (2.8 < Paux < 7.5 MW, 3.8 × 1019 < ne < 6 × 1019 m−3, RF-only and RF + NBI heating scenarios, both grad-B drift directions, and even He ion majority plasmas) (Sun et al. in Nucl. Fusion, 2020). A window of edge B concentration for stable long pulse operation was identified: too low and ELMs return, too high and the discharge suffers radiative collapse. The injection of boron powder above the minimum for ELM suppression coincided with the occurrence of an edge harmonic oscillation detected in magnetics (both on the high-field side and low-field side), in AXUV diodes near the upper X-point, divertor D α emission, and in a range of other diagnostics (Diallo et al. in: Proceedings of 2020 IAEA fusion energy conference, 2021). No harmonic oscillation was observed when ELMs were present, and stored energy was slightly increased at constant density during ELM suppression. Core tungsten emission during ELM suppression either increased or decreased relative to ELMy H-mode, but the W emission was maintained at acceptable levels. The threshold B injection rate was measured for several conditions, and found to increase with heating power. Li powder injection into comparable discharges also resulted in a short phase of ELM suppression, but density and stored energy both decreased due to the strong pumping effect of lithium; no edge harmonic oscillation was observed with Li injection, indicating that the ELM suppression mechanisms differ. The new set of B-seeded, ELM-suppressed discharges exhibited certain characteristics of quiescent H-mode (Burrell et al. in Phys Plasmas 8:2153, 2001), but did not require high shear, counter beams, etc. The wide operating window and compatibility with RF-only discharges paves the way for future experiments targeting long pulse H-mode discharges with complete ELM suppression. [ABSTRACT FROM AUTHOR]

Published

2020

17. Results from a new flowing liquid Li limiter with TZM substrate during high confinement plasmas in the EAST device.

Author

Zuo, G. Z., Li, C. L., Maingi, R., Meng, X. C., Sun, Z., Xu, W., Qian, Y. Z., Huang, M., Tang, Z. L., Zhang, D. H., Zhang, L., Chen, Y. J., Mao, S. T., Wang, Y. M., Zhao, H. L., Andruczyk, D., Tritz, K., Gong, X. Z., and Hu, J. S.

Subjects

*PLASMA confinement devices, *PLASMA heating, *PLASMA interactions, *ENGINEERING mathematics, *STAINLESS steel, *CORROSION resistance, *LITHIUM ions, *PLASMA boundary layers

Abstract

A third generation flowing liquid lithium (FLiLi) limiter with a substrate made of TZM, an alloy with >99% Mo, was fabricated by conventional manufacturing techniques. TZM has a high corrosion resistance, a high sputtering threshold, and a good wettability to Li, as compared to stainless steel (SS), which had been used as an FLiLi substrate surface in 2014 and 2016. The third generation FLiLi was inserted into the edge in EAST H-mode plasmas in an upper single-null configuration with an ion grad-B drift toward the upper divertor with a limiter temperature of 330–380 °C and an auxiliary heating power of about 2–8 MW. Analysis has shown that by using TZM FLiLi, fuel particle recycling continuously decreased and near-complete edge localized mode elimination was achieved in H-mode plasmas with RF-only heating. The main impurities during the initial FLiLi discharges were Mo, Fe, and W resulting from strong plasma interaction at the Mo plate side, the SS collector, and the upper W divertor. Plasma stored energy increased by about 10 kJ in subsequent FLiLi discharges due to decreased impurity radiation. Engineering analysis shows a uniform lithium flow with an ∼80% Li coverage ratio on the limiter surface, similar to the second FLiLi, even though only one of two J × B pumps was functioning. Despite technical difficulties, the FLiLi gen.3 improved the overall plasma performance, providing support for flowing liquid Li plasma facing component applications in present and future devices. [ABSTRACT FROM AUTHOR]

Published

2020

18. Active Recycling Control Through Lithium Injection in EAST

Author

Canik, J. M., primary, Sun, Z., additional, Hu, J. S., additional, Zuo, G. Z., additional, Xu, W., additional, Huang, M., additional, Wang, L., additional, Xu, J., additional, Zhang, T., additional, Maingi, R., additional, Lunsford, R., additional, Diallo, A., additional, Mansfield, D., additional, Osborne, T., additional, and Tritz, K., additional

Published

2018

19. First Results of ELM Triggering With a Multichamber Lithium Granule Injector Into EAST Discharges

Author

Sun, Z., primary, Lunsford, R., additional, Maingi, R., additional, Hu, J. S., additional, Mansfield, D. K., additional, Diallo, A., additional, Tritz, K., additional, Canik, J., additional, Wang, Z., additional, Andruczyk, D., additional, Wang, Y. M., additional, Zuo, G. Z., additional, Huang, M., additional, Xu, W., additional, and Meng, X. C., additional

Published

2018

20. Upgraded flowing liquid lithium limiter for improving Li coverage uniformity and erosion resistance in EAST device

Author

Zuo, G. Z., primary, Hu, J. S., additional, Maingi, R., additional, Yang, Q. X., additional, Sun, Z., additional, Huang, M., additional, Chen, Y., additional, Yuan, X. L., additional, Meng, X. C., additional, Xu, W., additional, Gentile, C., additional, Carpe, A., additional, Diallo, A., additional, Lunsford, R., additional, Mansfield, D., additional, Osborne, T., additional, Tritz, K., additional, and Li, J. G., additional

Published

2017

21. Erratum: New Steady-State Quiescent High-Confinement Plasma in an Experimental Advanced Superconducting Tokamak.

Author

Hu, J. S., Sun, Z., Guo, H. Y., Li, J. G., Wan, B. N., Wang, H. Q., Ding, S. Y., Xu, G. S., Liang, Y. F., Mansfield, D. K., Maingi, R., Zou, X. L., Wang, L., Ren, J., Zuo, G. Z., Zhang, L., Duan, Y. M., Shi, T. H., and Hu, L. Q.

Subjects

*TOKAMAKS, *PLASMA confinement devices, *EXPERIMENTAL design

Abstract

A correction to the article "New Steady-State Quiescent High-Confinement Plasma in an Experimental Advanced Superconducting Tokamak" that was published in the 2015 issue is presented.

Published

2015