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Rotation and its shear can reduce the magnetohydrodynamic instabilities and enhance the confinement. The LHCD has been proposed as a possible means of rotation driving on a future fusion reactor. Exploring the mechanisms of LHCD rotation driving on the current tokamaks can provide important reference for future reactors. On EAST, it was previously shown that 2.45 GHz LHCD can drive plasma toroidal rotation and the change of edge plasma rotation leads the co-current core rotation to increase. At higher frequency, 4.6 GHz lower hybrid wave can more effectively drive co-current plasma toroidal rotation. On EAST, at the lower current, the effects of different LHCD power on plasma toroidal rotation are analyzed. Higher power LHCD has a better driving efficiency. The effect of safety factor (q) profile on toroidal rotation is also presented. The LHCD can change the profile of safety factor due to current drive. It is found that when the power exceeds 1.4MW, the q profile remains unchanged and the rotation changes only very slightly with LHCD power, suggesting that the current profile is closely related to rotation. In order to further analyze the dynamic process of plasma toroidal rotation driven by lower hybrid current drive on EAST, the toroidal momentum transport due to LHCD is deduced by using the modulated LHCD power injection. Based on the momentum balance equation, the toroidal momentum diffusion coefficient (χφ) and the toroidal momentum pinch coefficient (Vpinch) are obtained by the method of separation of variables and Fourier analysis for the region where the external momentum source can be ignored. It is found that the momentum diffusion coefficient (χφ) and momentum pinch coefficient (Vpinch) tend to increase from the core to the outer region. This is consistent with the characteristic that the toroidal rotation velocity first changes in the outer region and then propagates to the core when the toroidal rotation is driven by LHCD.
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Keywords:
- lower hybrid current drive /
- toroidal rotation velocity /
- safety factor /
- toroidal momentum transport
[1] Betti R, Freidberg J P 1995 Phys. Rev. Lett. 74 2949Google Scholar
[2] Rice J E, Podpaly Y A, Reinke M L, Gao C, Shiraiwa S, Terry J L, Theiler C, Wallace G M, Bonoli P T, Brunner D 2013 Nucl. Fusion. 53 093015Google Scholar
[3] Rice J E, Gao C, Mumgaard R, et al. 2016 Nucl. Fusion. 56 036015Google Scholar
[4] Chouli B, Fenzi C, Garbet X, et al. 2014 Plasma Phys. Controlled Fusion. 56 095018Google Scholar
[5] Chouli B, Fenzi C, Garbet X, Bourdelle C, Sarazin Y, Rice J, Aniel T, Artaud J F, Baiocchi B, Basiuk V, Cottier P, Decker J, Imbeaux F, Irishkin M, Mazon D, Schneider M, the Tore Supra Team 2015 Plasma Phys. Controlled Fusion. 57 125007Google Scholar
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[7] Yin X H, Chen J, Hu R J, Yi Y Y, Wang F D, Fu J, Ding B J, Wang M, Liu F K, Zang Q, Shi Y J, Lyu B, Wan B N, the EAST team 2017 Chin. Phys. B 26 115203Google Scholar
[8] Koide Y, Tuda T, Ushigusa K, Asakura N, Sakasai A, Ide S, Ishida S, Kikuchi M, Azumi M, Funahashi A 1992 Plasma Phys. Control. Nucl. Fusion. Res. 1 777
[9] Eriksson L G, Hellsten T, Nave F, Brzozowski J, Holmström K, Johnson T, Ongena J, Zastrow K D 2009 Plasma Phys. Controlled Fusion. 51 044008Google Scholar
[10] Nave M F F, Kirov K, Bernardo J, Brix M, Ferreira J, Giroud C, Hawkes N, Hellsten T, Jonsson T, Mailloux J, Ongena J, Parra F, JET Contributors 2017 Nucl. Fusion. 57 034002Google Scholar
[11] Wan B N, Liang Y F, Gong X Z, Li J G, Xiang N, Xu G S, Sun Y W, Wang L, Qian J P, Liu H Q, Zhang X D, Hu L Q, Hu J S, Liu F K, Hu C D, Zhao Y P, Zeng L, Wang M, Xu H D, Luo G N 2017 Nucl. Fusion. 57 102019Google Scholar
[12] Ding B J, Li Y C, Zhang L, et al. 2015 Nucl. Fusion. 55 093030Google Scholar
[13] Lyu B, Wang F D, Pan X Y, et al. 2014 Rev. Sci. Instruments. 85 11E406Google Scholar
[14] Lyu B, Chen J, Hu R J, et al. 2016 Rev. Sci. Instruments. 87 11E326Google Scholar
[15] Lyu B, Chen J, Hu R J, et al. 2018 Rev. Sci. Instruments. 89 10F112Google Scholar
[16] Li Y Y, Fu J, Lyu B, Du X W, Li C Y, Zhang Y, Yin X H, Yu Y, Wang Q P, von Hellermann M 2014 Rev. Sci. Instruments. 85 11E428Google Scholar
[17] Rice J E, Ince-Cushman A, deGrassie J S, Eriksson L G, Sakamoto Y, Scarabosio A, Bortolon A, Burrell K H, Duval B P, Fenzi-Bonizec C, Greenwald M J, Groebner R J, Hoang G T, Koide Y, Marmar E S, Pochelon A, Podpaly Y 2007 Nucl. Fusion. 47 1618Google Scholar
[18] Liu H Q, Qian J P, Jie Y X, et al. 2016 Rev. Sci. Instruments. 87 11D903Google Scholar
[19] Yoshida M, Koide Y, Takenaga H, Urano H, Oyama N, Kamiya K, Sakamoto Y, Kamada Y and the JT-60 Team 2006 Plasma Phys. Control. Fusion. 48 1673Google Scholar
[20] Yoshida M, Koide Y, Takenaga H, Urano H, Oyama N, Kamiya K, Sakamoto Y, Matsunaga G, Kamada Y and the JT-60U Team 2007 Nucl. Fusion. 47 856Google Scholar
[21] Ida K, Miura Y, Itoh K, Itoh S I, Matsuda T 1998 J. Phys. Soc. Japan. 67 4089Google Scholar
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图 1 典型参数随时间变化的波形图 (#70938) (a) 等离子体电流 (黑色), 低杂波功率 (蓝色); (b) 环电压 (黑色)和内感 (蓝色); (c) 芯部弦平均电子密度; (d) 储能; (e) 芯部电子温度 (黑色)和芯部离子温度 (红色); (f) 芯部环向速度变化
Figure 1. Waveforms of typical parameters of an LHCD shot (#70938) on EAST: (a) Plasma current (black) and LHCD power)(blue); (b) loop voltage (black) and internal inductance (blue); (c) central line averaged electron density; (d) stored energy; (e) central ion (red) and electron (black) temperature; (f) the change of core toroidal rotation velocity.
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[1] Betti R, Freidberg J P 1995 Phys. Rev. Lett. 74 2949Google Scholar
[2] Rice J E, Podpaly Y A, Reinke M L, Gao C, Shiraiwa S, Terry J L, Theiler C, Wallace G M, Bonoli P T, Brunner D 2013 Nucl. Fusion. 53 093015Google Scholar
[3] Rice J E, Gao C, Mumgaard R, et al. 2016 Nucl. Fusion. 56 036015Google Scholar
[4] Chouli B, Fenzi C, Garbet X, et al. 2014 Plasma Phys. Controlled Fusion. 56 095018Google Scholar
[5] Chouli B, Fenzi C, Garbet X, Bourdelle C, Sarazin Y, Rice J, Aniel T, Artaud J F, Baiocchi B, Basiuk V, Cottier P, Decker J, Imbeaux F, Irishkin M, Mazon D, Schneider M, the Tore Supra Team 2015 Plasma Phys. Controlled Fusion. 57 125007Google Scholar
[6] Shi Y, Xu G, Wang F, Wang M, Fu J, Li Y, Zhang W, Chang J, Lv B, Qian J, Shan J, Liu F, Ding S, Wan B, Lee S G, Bitter M, Hill K 2011 Phys. Rev. Lett. 106 235001Google Scholar
[7] Yin X H, Chen J, Hu R J, Yi Y Y, Wang F D, Fu J, Ding B J, Wang M, Liu F K, Zang Q, Shi Y J, Lyu B, Wan B N, the EAST team 2017 Chin. Phys. B 26 115203Google Scholar
[8] Koide Y, Tuda T, Ushigusa K, Asakura N, Sakasai A, Ide S, Ishida S, Kikuchi M, Azumi M, Funahashi A 1992 Plasma Phys. Control. Nucl. Fusion. Res. 1 777
[9] Eriksson L G, Hellsten T, Nave F, Brzozowski J, Holmström K, Johnson T, Ongena J, Zastrow K D 2009 Plasma Phys. Controlled Fusion. 51 044008Google Scholar
[10] Nave M F F, Kirov K, Bernardo J, Brix M, Ferreira J, Giroud C, Hawkes N, Hellsten T, Jonsson T, Mailloux J, Ongena J, Parra F, JET Contributors 2017 Nucl. Fusion. 57 034002Google Scholar
[11] Wan B N, Liang Y F, Gong X Z, Li J G, Xiang N, Xu G S, Sun Y W, Wang L, Qian J P, Liu H Q, Zhang X D, Hu L Q, Hu J S, Liu F K, Hu C D, Zhao Y P, Zeng L, Wang M, Xu H D, Luo G N 2017 Nucl. Fusion. 57 102019Google Scholar
[12] Ding B J, Li Y C, Zhang L, et al. 2015 Nucl. Fusion. 55 093030Google Scholar
[13] Lyu B, Wang F D, Pan X Y, et al. 2014 Rev. Sci. Instruments. 85 11E406Google Scholar
[14] Lyu B, Chen J, Hu R J, et al. 2016 Rev. Sci. Instruments. 87 11E326Google Scholar
[15] Lyu B, Chen J, Hu R J, et al. 2018 Rev. Sci. Instruments. 89 10F112Google Scholar
[16] Li Y Y, Fu J, Lyu B, Du X W, Li C Y, Zhang Y, Yin X H, Yu Y, Wang Q P, von Hellermann M 2014 Rev. Sci. Instruments. 85 11E428Google Scholar
[17] Rice J E, Ince-Cushman A, deGrassie J S, Eriksson L G, Sakamoto Y, Scarabosio A, Bortolon A, Burrell K H, Duval B P, Fenzi-Bonizec C, Greenwald M J, Groebner R J, Hoang G T, Koide Y, Marmar E S, Pochelon A, Podpaly Y 2007 Nucl. Fusion. 47 1618Google Scholar
[18] Liu H Q, Qian J P, Jie Y X, et al. 2016 Rev. Sci. Instruments. 87 11D903Google Scholar
[19] Yoshida M, Koide Y, Takenaga H, Urano H, Oyama N, Kamiya K, Sakamoto Y, Kamada Y and the JT-60 Team 2006 Plasma Phys. Control. Fusion. 48 1673Google Scholar
[20] Yoshida M, Koide Y, Takenaga H, Urano H, Oyama N, Kamiya K, Sakamoto Y, Matsunaga G, Kamada Y and the JT-60U Team 2007 Nucl. Fusion. 47 856Google Scholar
[21] Ida K, Miura Y, Itoh K, Itoh S I, Matsuda T 1998 J. Phys. Soc. Japan. 67 4089Google Scholar
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