Influence of Conical Wire Array Geometry on Flow and Temperature Profiles Measured via Thomson Scattering and Optical Techniques

Abstract

Conical wire arrays with different opening angles are used as load of a 400kA, 1kA/ns generator. The differences in opening angle allow the study of the influence of the array geometry on the jet properties. The characterization of the jets is performed using a combination of advanced diagnostic techniques, including moir\'e schlieren deflectometry, visible self-emission spectroscopy, and optical Thomson scattering. The results reveal that, under the experimental conditions, the plasma jets exhibit electron temperatures ranging from 8 to 17 eV, increasing along the axial direction. In contrast, the ion temperature decreases from approximately 35 eV near the base of the jet to about 20 eV at higher axial positions. The electron density profile peaks at 4 × 1018 cm-3 in the central lower region of the jet and decreases with height exponentially with a characteristic lenght Ln = 2.86 mm. This behavior is reproducible and independent of the conical array geometry. However, the cone opening angle significantly affect the jet propagation velocity, with larger opening angles producing higher axial velocities (Vφ=40 ≈ 1253 km/s, Vφ=20 ≈ 985 km/s), demonstrating that the cone geometry provides effective control over the jet propagation velocity.