Abstract
In this paper, we propose an efficient diagnostic technique for determining spatially resolved measurements of the ion density ratio in a magnetized two-ion species plasma. Shear Alfvén waves were injected into a mixed helium–neon plasma using a magnetic loop antenna, for frequencies spanning the ion cyclotron regime. Two distinct propagation bands are observed, bounded by $\omega < \varOmega _\textrm {Ne}$ and $\omega _{ii} < \omega < \varOmega _\textrm {He}$ , where $\omega _{ii}$ is the ion–ion hybrid cutoff frequency and $\varOmega _\textrm {He}$ and $\varOmega _\textrm {Ne}$ are the helium and neon cyclotron frequencies, respectively. A theoretical analysis of the cutoff frequency was performed and shows it to be largely unaffected by kinetic electron effects and collisionality, although it can deviate significantly from $\omega _{{ii}}$ in the presence of warm ions due to ion finite Larmor radius effects. A new diagnostic technique and accompanying algorithm was developed in which the measured parallel wavenumber $k_\parallel$ is numerically fit to the predicted inertial Alfvén wave dispersion in order to resolve the local ion density ratio. A major advantage of this algorithm is that it only requires a measurement of $k_\parallel$ and the background magnetic field in order to be employed. This diagnostic was tested on the Large Plasma Device at UCLA and was successful in yielding radially localized measurements of the ion density ratio.
Highlights
Understanding the propagation of shear Alfvén waves in multi-ion species plasmas, and the consequent interaction of the waves with the plasma, is important in space and astrophysical settings as well as in the laboratory
As we showed in the previous section that the cutoff frequency is the same for all electron temperatures, we consider the ‘cold’ limit (Z(ζ ) → −1/ζ ) for all particle species, while retaining ion finite Larmor radius (FLR) effects
An additional caveat of large ion FLR effects is that they tend to excite additional propagation bands near the cutoff, which may mask the exact value of the cutoff frequency and further limit this diagnostic’s accuracy
Summary
Understanding the propagation of shear Alfvén waves in multi-ion species plasmas, and the consequent interaction of the waves with the plasma, is important in space and astrophysical settings as well as in the laboratory. Each additional ion species in a magnetized plasma introduces a new resonance (at that ion’s cyclotron frequency) and an associated cutoff for the shear Alfvén wave, leading to propagation in a series of frequency bands, one per ion species. Shear Alfvén waves propagating in bands near or above the species’ gyrofrequencies are called electromagnetic ion cyclotron (EMIC) waves IP address: 18.207.210.1, on 02 Nov 2021 at 10:49:00, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms.
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