Xinliang Xu, Zhanhui Wang, Nami Li, Na Wu, Yulin Zhou, Xueke Wu, Cailong Fu
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引用次数: 0
摘要
为了将托卡马克边缘多尺度磁流体动力学(MHD)事件和传输模拟(如边缘局部模式(ELM)循环)结合起来,我们开发了一种新的集成模型。作为原理验证,我们首先从一组三场双流体模型方程出发,其中包括压力、电流和涡度。通过取轴对称分量的时间平均值,将方程分离成轴对称分量的缓慢演化部分。时间平均通量是波动量的二次方,它作为时间平均轴对称量的驱动项,决定了等离子体的传输,从而决定了等离子体剖面的大尺度演变。然后利用该模型模拟了 HL-2A 的 ELM 循环。通过耦合模拟得到的解与实验结果相比,在 ELM 尺寸和基座恢复时间方面取得了良好的一致性。在一次 ELM 循环模拟中,耦合代码比独立代码最多可提速 30 倍。
HL-2A's ELM cycle simulations by integrating BOUT++'s drift MHD and transport code
A new integrating model has been developed to couple tokamak edge multiscale magnetohydrodynamic (MHD) events and transport simulations, such as edge-localized mode (ELM) cycles. As a proof of principle, we first start from a set of three-field two-fluid model equations, which includes the pressure, current, and vorticity. The equations are separated into the slowly evolving part of the axisymmetric component by taking a time average of the axisymmetric component. The time-averaged fluxes, which are quadratic in fluctuating quantities, act as driven terms for the time-averaged axisymmetric quantities that determine the plasma transport, and therefore the large-scale evolution of the plasma profiles. Then the HL-2A's ELM cycles are simulated using the model. Good agreements of ELM size and pedestal recovery time have been achieved for the solutions obtained from the coupled simulation compared with experiment. For one ELM cycle simulation, the coupled code can achieve a speedup of a factor of up to 30 over standalone code.
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