Helicon wave damping coefficient of Chinese fusion engineering testing reactor plasma

Xin-Xia Li; Guo-Zhuang Li; Hong-Bo Liu

doi:10.7498/aps.69.20200222

Journals >Acta Physica Sinica >Volume 69 >Issue 14 >Page 145201-1 > Article

Acta Physica Sinica
Vol. 69, Issue 14, 145201-1 (2020)

Helicon wave damping coefficient of Chinese fusion engineering testing reactor plasma

Xin-Xia Li^1、2、*, Guo-Zhuang Li¹, and Hong-Bo Liu¹

Author Affiliations

¹School of Nuclear Science and Technology, University of South China, Hengyang 421001, China

²Institute of Plasma Physics, Chinese Academy of Sciences, Hefei 230031, China

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DOI: 10.7498/aps.69.20200222 Cite this Article

Xin-Xia Li, Guo-Zhuang Li, Hong-Bo Liu. Helicon wave damping coefficient of Chinese fusion engineering testing reactor plasma[J]. Acta Physica Sinica, 2020, 69(14): 145201-1 Copy Citation Text

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The dependence of and its components on .

Fig. 1. The dependence of

and its components on

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The relationship of the wave damping factor on wave frequency. The parameters used here are , ne0 = 1 × 1020 m–3, B = 5 T, .

Fig. 2. The relationship of the wave damping factor on wave frequency. The parameters used here are

, n_e0 = 1 × 10²⁰ m^–3, B = 5 T,

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$The effect of wave initial parallel refractive index and plasma density on wave damping factor. The plasma temperature is , magnetic filed .$

Fig. 3. The effect of wave initial parallel refractive index

and plasma density on wave damping factor. The plasma temperature is

, magnetic filed

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Fig. 4. The dependence of wave damping factor G on plasma temperature. The parameters used here are f = 800 MHz,

, B = 5.0 T.

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Fig. 5. The relationship between the damping ratio and the wave frequency on CFETR.

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$The power deposition density profile of helicon wave under the CFETR hybrid mode, the power inject is, parallel refractive index , the wave frequency is 800 MHz.$

Fig. 6. The power deposition density profile of helicon wave under the CFETR hybrid mode, the power inject is

, parallel refractive index

, the wave frequency is 800 MHz.

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Fig. 7. The current drive density profile of helicon wave under the CFETR hybrid mode. The parameters used are the same as in Fig. 6.

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	数值计算结果		数表结果^[10]
ξ	Z_R	Z_I	Z_R	Z_I
0	0	0.177245×10¹	0	0.177245×10¹
0.2	–0.389502	0.170296×10¹	–0.389502	0.170295×10¹
0.4	–0.719887	0.151039×10¹	0.719887	0.151039×10¹
0.6	–0.949526	0.123660×10¹	–0.949256	0.123660×10¹
1.0	–1.076159	0.652049×10⁰	1.076160	0.652049×10⁰
2.0	–0.602681	0.324636×10^–1	0.602681	0.324636×10^–1
4.0	–0.258696	0.199463×10^–6	0.258696	0.199463×10^–6
6.0	–0.169085	0.411125×10^–15	0.169086	0.411124×10^–15

Table 1.

Numerical results of plasma dispersion function.

等离子体色散函数数值结果比较

Xin-Xia Li, Guo-Zhuang Li, Hong-Bo Liu. Helicon wave damping coefficient of Chinese fusion engineering testing reactor plasma[J]. Acta Physica Sinica, 2020, 69(14): 145201-1

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