Effects of width and density of supersonic molecule beam on penetration depth of tokamak

Wu Xue-Ke; Sun Xiao-Qin; Liu Yin-Xue; Li Hui-Dong; Zhou Yu-Lin; Wang Zhan-Hui; Feng Hao

doi:10.7498/aps.66.195201

Abstract

The penetration depth and the fueling efficiency of the supersonic molecular beam injection (SMBI) are affected by both the intrinsic parameters of the SMBI and the parameters of background plasma. The purpose of the present paper is to explore the possible methods of improving the fueling efficiency of SMBI by varying the beam parameters. The penetration depths and the transport processes of SMBI with different beam densities and different beam widths are studied using the trans-neut module of the three-dimensional (3D) edge turbulence simulation code BOUT++. In our present study, the number of the injected molecules per unit time the injection speed and the injected flux are kept constant throughout the SMB fueling process, but the beam density and beam width are adjusted. The simulation is based on the real magnetic configuration of the HL-2A tokamak. Our results indicate that the deeper injection depth can be obtained with a supersonic molecular beam (SMB) with smaller density and larger width. However, the injection depth decreases when the beam density or the beam width increases. The residence time of the beam front can be lengthened by increasing the beam density and widening the beam width. If the beam density increases or the beam width enlarges, not only the injection depth decreases, but also the residence time shortens. The front of the atom density exhibits the behaviors analogous to that of the SMB, namely, both its depth and its residence time decreases with beam density increasing and beam width decreasing. At the same time, the dissociation rate has a larger range in the spatiotemporal coordinate. The global growth of dissociation rate is inhibited by the molecular dissociation localization. However, the localization of the molecular dissociation accelerates the local growth of the dissociation rate, and the global growth of the molecular dissociation rate is promoted. When the promoting effect is dominant, under the condition of constant flux and fixed injection speed, the smaller molecular injection width will lead to the shallower molecular penetration depth. The simulation results suggest that if we attempt to promote the fueling efficiency and to increase the injection depth of SMBI, we should utilize the SMBI with a smaller density and larger beam width. Of course, the concrete influences of the SMBI on injection depth and fueling efficiency should be studied further by varying other relevant parameters of the SMB and the backgroud plasma.

Keywords:

Authors and contacts

1.
School of Sciences, Xihua University, Chengdu 610039, China;
2.
Southwestern Institute of Physics, Chengdu 610041, China}

Corresponding author: Li Hui-Dong, huidongli@mail.xhu.edu.cn;zhwang@swip.ac.cn ; Wang Zhan-Hui, huidongli@mail.xhu.edu.cn;zhwang@swip.ac.cn ;

Funds: Project supported by the National Natural Science Fund for Young Scientists of China (Grant No. 11605143), the National Natural Science Foundation of China (Grant No. 11575055), the National ITER Program of China (Contract No. 2014GB113000), China National Magnetic Confinement Fusion Science Program (Grant No. 2013GB107001), and the Open Research Subject of Key Laboratory of Advanced Computation in Xihua University, China (Grant Nos. szjj2017-011, szjj2017-012).

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[22]	Shi Y F, Wang Z H, Ren Q L, Sun A P, Yu D L, Guo W F, Xu M 2017 Chin. Phys. B 26 055201

Cited By

[1]	Sajjad S, Gao X, Ling B, Bhatti S H, Ang T 2009 Phys. Lett. A 373 1133
[2]	Baylor L R, Jernigan T C, Combs S K, Houlberg W A, Owen L W, Rasmussen D A, Maruyama S, Parks P B 2000 Phys. Plasmas 7 1878
[3]	Yao L H, Zhao D W, Feng B B, Chen C Y, Zhou Y, Han X Y, Li Y G, Jerome B, Duan X R 2010 Plasma Sci. Technol. 12 529
[4]	Yu D L, Chen C Y, Yao L H, Dong J Q, Feng B B, Zhou Y, Shi Z B, Zhou J, Han X Y, Zhong W L, Cui C H, Huang Y, Cao Z, Liu Y, Yan L W, Yang Q W, Duan X R, Liu Y 2012 Nucl. Fusion 52 082001
[5]	Xiao W W, Diamond P H, Zou X L, Dong J Q, Ding X T, Yao L H, Feng B B, Chen C Y, Zhong W L, Xu M 2012 Nucl. Fusion 52 114027
[6]	Ma Q, Yu D L, Chen C Y, Wei Y L, Zhong W L, Zou X L, Zuo H Y, Du J L, Liu L, Dong C F, Shi Z B, Zhao K J, Feng B B, Zhou Y, Wang Z H, Xu M, Liu Y, Yan L W, Yang Q W, Yao L H, Ding X T, Dong J Q, Duan X R, Liu Y, HL-2A Team 2016 Nucl. Fusion 56 126008
[7]	Huang D W, Chen Z Y, Tong R H, Yan W, Wang S Y, Wei Y N, Ma T K, Dai A J, Wang X L, Jiang Z H, Yang Z J, Zhuang G, Pan Y, J-TEXT Team 2017 Plasma Phys. Contr. Fusion 59 085002
[8]	Sun H J, Ding X T, Yao L H, Feng B B, Liu Z T, Duan X R, Yang Q W 2010 Plasma Phys. Contr. F. 52 045003
[9]	Braams B J 1996 Contrib. Plasma Phys. 36 276
[10]	Vold E L, Najmabadi F, Conn R W 1992 Nucl. Fusion 32 1433
[11]	Rognlien T D, Braams B J, Knoll D A 1996 Contrib. Plasma Phys. 36 105
[12]	Rognlien T D, Ryutov D D, Mattor N, Porter G D 1999 Phys. Plasmas 6 1851
[13]	Dudson B D, Umansky M V, Xu X Q, Snyder P B, Wilson H R 2009 Comput. Phys. Commun. 180 1467
[14]	Xu X Q, Umansky M V, Dudson B, Snyder R B 2008 Commun. Comput. Phys. 4 949
[15]	Umansky M V, Xu X Q, Dudson B, Lodestro L L, Myra J R 2009 Comput. Phys. Commun. 180 887
[16]	Landman I S, Janeschitz G 2007 J. Nucl. Mater. 363 1061
[17]	Wang Z H, Xu X Q, Xia T Y, Rognlien T D 2014 Nucl. Fusion 54 043019
[18]	Wang Y H, Guo W F, Wang Z H, Ren Q L, Sun A P, Xu M, Wang A K, Xiang N 2016 Chin. Phys. B 25 106601
[19]	Zhou Y L, Wang Z H, Xu X Q, Li H D, Feng H, Sun W G 2015 Phys. Plasmas 22 012503
[20]	Zhou Y L, Wang Z H, Xu M, Wang Q, Nie L, Feng H, Sun W G 2016 Chin. Phys. B 25 095201
[21]	Wu X K, Li H D, Wang Z H, Feng H, Zhou Y L 2017 Chin. Phys. B 26 065201
[22]	Shi Y F, Wang Z H, Ren Q L, Sun A P, Yu D L, Guo W F, Xu M 2017 Chin. Phys. B 26 055201

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Vol. 66, Issue 19 - 2017-10-05

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