Impact of impurities on drift wave instabilities in reversed-field pinch plasmas

Jingchun Li, Songfen Liu, Yilong Zhang, Jiaqi Dong, Wei Kong, and P. Shi

Phys. Rev. E 106, 045203 – Published 12 October 2022

Abstract

The drift wave in the presence of impurity ions was investigated numerically in reversed-field pinch plasmas, using the gyrokinetic integral eigenmode equation. By comparing the results of regular and hollow plasma density profiles, it was found that the ion temperature gradient mode for the hollow density profile case is much harder to excite. For the impurity effects, when the impurity density gradient is opposite to the electrons, namely when $L_{e z}$ ( $L_{e z} = L_{n e} / L_{n z}$ with $1 / L_{n}$ being the density gradient scale length, and the subscript “ $e$ ” and “ $z$ ” indicates electrons and impurity ions, respectively) is negative, the impurities can enhance the instability. On the contrary, when $L_{e z}$ is positive, the instability is stabilized. Regarding the trapped electron mode (TEM), the growth rate for plasmas with a hollow density profile remains smaller than that of the standard density gradient. There exists a threshold in $L_{e z}$ . When $L_{e z}$ is less than this value, the impurities destabilize the TEMs, while when $L_{e z}$ is greater than this value, the impurities stabilize the TEMs. In addition, the influence of the collisionality on the TEMs was also studied.