Effect of magnetic shearing on thermal transport of electrons in magnetic islands
-
摘要: 通过数值求解托卡马克等离子体能量输运方程,研究了磁剪切参数对磁岛内电子温度分布和热输运的影响。结果表明,对于不同的安全因子的径向分布,磁剪切参数会影响有效径向热输运系数,剪切程度越高,有效径向热输运系数
${\chi _r}$ 越大;当磁场扰动程度足够高时,高剪切对有效径向热输运系数${\chi _r}$ 影响会降低。Abstract: The influence of magnetic shear parameters on the electron temperature distribution and heat transport in the magnetic island were studied by numerically solving the tokamak plasma energy transport equation. The results show that for different radial distributions of the safety factor, the magnitude of the magnetic shear parameter will affect the magnitude of the effective radial heat transport coefficient. The higher the shear degree, the greater the effective radial heat transport${\chi _r}$ coefficient. And when the magnetic field perturbation degree is high enough, the effect of high shear on radial heat transport${\chi _r}$ will be reduced.-
Key words:
- magnetic island /
- effective radial heat transport /
- magnetic shear
-
图 2
$w = 0.005a$ 和$w = 0.05a$ 时,$\log \left( {{\chi _{r}}/{\chi _ \bot }\;} \right)$ 随剪切长度$ {L_q} $ 的变化Figure 2. With
$w = 0.005a$ and$w = 0.05a$ ,$\log \left( {{\chi _{r}}/{\chi _ \bot }\;} \right)$ vs shear length$ {L_q} $ 
图 3 磁剪切大小随径向位置变化的安全因子径向分布图
Figure 3. Radial distribution diagram of safety factor of magnetic shear size vs radial position
图 4
$\log \left( {{\chi _{r}}/{\chi _ \bot }\;} \right)$ 随$\log \left( {{\chi _\parallel }/{\chi _ \bot }\;} \right)$ 变化图Figure 4. variation diagram of
$\log \left( {{\chi _{r}}/{\chi _ \bot }\;} \right)$ vs$\log \left( {{\chi _\parallel }/{\chi _ \bot }\;} \right)$ 
图 5
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,$ {L_q} = 0.05a $ ,$\phi = 0$ 时磁岛在$r - \theta $ 平面上的磁面结构图Figure 5. When
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,$ {L_q} = 0.05a $ ,$\phi = 0$ , magnetic surface structure diagram of magnetic islandon$r - \theta $ plane
图 6
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,$ {L_q} = 0.05a $ 时,各阶相加后的电子温度径向分布图Figure 6. When
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,$ {L_q} = 0.05a $ , sum of each order of electron temperature radial distribution
图 7 不同径向格点数的电子温度的等高线分布图
Figure 7. Contour distribution map of electron temperature with different radial grid points
图 8
$\psi {\text{ = }}1 \times {10^{{-}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ 时,$\log ({\chi _r}/{\chi _ \bot })$ 的径向分布图Figure 8. When
$\psi {\text{ = }}1 \times {10^{{-}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ , radial distribution diagram of$\log ({\chi _r}/{\chi _ \bot })$ 
图 9
$\psi {\text{ = }}1 \times {10^{{{ - }}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ ,$\phi = 0$ 时磁岛在$r - \theta $ 平面上的磁面结构图Figure 9. When
$\psi {\text{ = }}1 \times {10^{{{ - }}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ ,$\phi = 0$ , magnetic surface structure diagram of magnetic island on$r - \theta $ plane
图 10
$\psi {\text{ = }}1 \times {10^{{{ - }}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ 时,各阶相加后的电子温度径向分布图Figure 10. When
$\psi {\text{ = }}1 \times {10^{{{ - }}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ , sum of each order of electron temperature radial distribution
图 11
$\psi {\text{ = }}1 \times {10^{{{ - }}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ 时,电子温度的等高线分布图Figure 11. When
$\psi {\text{ = }}1 \times {10^{{{ - }}4}}{a}{{B}_{t}}$ ,${L_q} = 0.05a$ , contour distribution map of electron temperature
图 12
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,${L_q} = 0.3a$ 时,$\log ({\chi _r}/{\chi _ \bot })$ 的径向分布图Figure 12. When
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,${L_q} = 0.3a$ , radial distribution diagram of$\log ({\chi _r}/{\chi _ \bot })$ 
图 13
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,${L_q} = 0.3a$ ,$\phi = 0$ 时磁岛在$r - \theta $ 平面上的磁面结构图Figure 13. When
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,${L_q} = 0.3a$ ,$\phi = 0$ , magnetic surface structure diagram of magnetic island on$r - \theta $ plane
图 14
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,${L_q} = 0.3a$ 时,各阶相加后的电子温度径向分布图Figure 14. When
$\psi {\text{ = }}2 \times {10^{{{ - }}3}}{a}{{B}_{t}}$ ,${L_q} = 0.3a$ , sum of each order of electron temperature radial distribution -
[1] WESSON J, CAMPBELL D. Tokamaks [M]. Oxford: Oxford University Press, 2004. [2] GUNTER S, YU Q, LACKNER K. Modelling of heat transport in magnetised plasmas using non-aligned coordinates[J] . Journal Computational Journal of Computational Physics,2005,209(1):354 − 397. doi: 10.1016/j.jcp.2005.03.021 [3] RUTHERFORD P H. Nonlinear growth of the tearing mode[J] . Physics of Fluids,1973,16(11):1903 − 1908. doi: 10.1029/GM030p0292 [4] FITZPATRICK R. Helical temperature perturbations associated with tearing modes in tokamak plasmas[J] . Physics of Plasmas,1995,2(2):825 − 838. [5] FURTH H P. Prevalent instability of nonthermal plasmas[J] . Physics of Fluids,1963,6(1):48 − 57. [6] 王水, 李罗权. 磁场重联[M]. 合肥: 安徽教育出版社, 1999. [7] CHEN X L, MORRISON P J. Resistive tearing instability with equilibrium shear flow[J] . Physics of Fluids B:Plasma Physics,1990,2(3):495 − 507. doi: 10.1063/1.859339 [8] ZWEIBEL E G, YAMADA M. Magnetic Reconnection in Astrophysical and Laboratory Plasmas[J] . Annual Review of Astronomy and Astrophysics,2009,47(1):291 − 332. doi: 10.1146/annurev-astro-082708-101726 [9] YU Q, GÜNTER S. Modeling of the nonlinear growth of neoclassical tearing modes[J] . Physics of Plasmas,1998,5(11):3924 − 3928. doi: 10.1063/1.873112 [10] GAROFALO A M, BURRELL K H, DEBOO J C, et al. Observation of plasma rotation driven by static nonaxisymmetric magnetic fields in a tokamak[J] . Physical Review Letters,2008,101(19):195005. doi: 10.1103/PhysRevLett.101.195005 [11] LA Haye R J. Neoclassical tearing modes and their control[J] . Physics of Plasmas,2006,13(5). doi: 10.1063/1.2180747 [12] IDA K, NAGAOKA K, INAGAKI S, et al. Overview of transport and MHD stability study: Focusing on the impact of magnetic field topology in the large helical device[J] . Nuclear Fusion,,2015,55(10). doi: 10.1088/0029-5515/55/10/104018 [13] HAWRYLUK R J, BATHA S, BLANCHARD W, et al. Fusion plasma experiments on TFTR: A 20 year retrospective[J] . Physics of Plasmas,1998,5(5):1577 − 1589. doi: 10.1063/1.872825 [14] ONO M, KAITA R. Recent progress on spherical torus research[J] . Physics of Plasmas,2015,22(4). doi: 10.1063/1.4915073 [15] FURTH H P. Thermal equilibrium and stability of tokamak discharges[J] . Physics of Fluids,1970,13(12):3020 − 3030. [16] REN C, CHU M S, CALLEN J D. Magnetic island deformation due to sheared flow and viscosity[J] . Physics of Plasmas,1999,6(4):1203 − 1207. doi: 10.1063/1.873363 [17] SCHMITZ O, EVANS T E, FENSTERMACHER M E, et al. Formation of a three-dimensional plasma boundary after decay of the plasma response to resonant magnetic perturbation fields[J] . Nuclear Fusion,2014,54(1):012001. doi: 10.1088/0029-5515/54/1/012001 [18] KAMADA Y. Special issue: overview and summary reports from the 25th Fusion Energy Conference (St Petersburg, Russian Federation, 13−18 October 2014)[J] . Nuclear Fusion,2015,55(10):100201. doi: 10.1088/0029-5515/55/10/100201 [19] CROMBE K, ANDREW Y, BRIX M, et al. Poloidal rotation dynamics, radial electric field, and neoclassical theory in the jet internal-transport-barrier region[J] . Physical Review Letters,2005,95(15):155003. doi: 10.1103/PhysRevLett.95.155003 [20] 刘勇强. 局域热源对磁岛热输运的研究以及对撕裂模不稳定性影响 [D]. 上海: 东华大学, 2018. [21] SUCKEWER S, EUBANK H P, GOLDSTON R J, et al. Toroidal plasma rotation in the princeton large torus induced by neutral-beam injection[J] . Physical Review Letters,1979,43(3):207 − 210. doi: 10.1103/PhysRevLett.43.207 [22] TALA T, ANDREW Y, CROMBÉ K, et al. Toroidal and poloidal momentum transport studies in JET[J] . Nuclear Fusion,2007,47(8):1012 − 1023. doi: 10.1088/0029-5515/47/8/036 [23] 阳明, 王乐, 林文斌. 不同初始平衡磁剪切对共振磁扰动诱发的双撕裂模的影响[J] . 科技通报,2019,35(7):21 − 5,39. doi: 10.13774/j.cnki.kjtb.2019.07.005 [24] 胡希伟. 等离子体理论基础 [M]. 北京: 北京大学出版社, 2006. [25] GRIERSON B A, BURRELL K H, SOLOMON W M, et al. Collisionality scaling of main-ion toroidal and poloidal rotation in low torque DIII-D plasmas[J] . Nuclear Fusion,2013,53(6):063010. doi: 10.1088/0029-5515/53/6/063010 [26] SCOTT B D, DRAKE J F, HASSAM A B. Nonlinear stability of drift-tearing modes[J] . Physical Review Letters,1985,54(10):1027 − 1030. doi: 10.1103/PhysRevLett.54.1027 [27] ROSENBLUTH M N. Nonlinear properties of the internal m=1 kink instability in the cylindrical tokamak[J] . Physics of Fluids,1973,16(11):1894 − 1902. doi: 10.1063/1.1694231 -
下载:
点击查看大图
计量
- 文章访问数: 20
- HTML全文浏览量: 9
- PDF下载量: 1
- 被引次数: 0
