Evolution of longitudinal plasma-density profiles in discharge capillaries for plasma wakefield accelerators

TL;DR

This study employs advanced diagnostics to characterize the evolution of plasma density and temperature in discharge capillaries, revealing a transition from flat-top to Gaussian profiles, crucial for optimizing plasma wakefield accelerators.

Contribution

It introduces a combined diagnostic approach for high-resolution, temporally and spatially resolved plasma density and temperature measurements in discharge capillaries.

Findings

Plasma density profiles evolve from flat-top to Gaussian within microseconds.

The diagnostics achieve unprecedented sensitivity and resolution.

Measured plasma temperatures range from 1 to 7 eV.

Abstract

Precise characterization and tailoring of the spatial and temporal evolution of plasma density within plasma sources is critical for realizing high-quality accelerated beams in plasma wakefield accelerators. The simultaneous use of two independent diagnostic techniques allowed the temporally and spatially resolved detection of plasma density with unprecedented sensitivity and enabled the characterization of the plasma temperature at local thermodynamic equilibrium in discharge capillaries. A common-path two-color laser interferometer for obtaining the average plasma density with a sensitivity of $2\times 10^{15}$ cm$^{-2}$ was developed together with a plasma emission spectrometer for analyzing spectral line broadening profiles with a resolution of $5\times 10^{15}$ cm$^{-3}$. Both diagnostics show good agreement when applying the spectral line broadening analysis methodology of Gigosos and Carde{\~n}oso. Measured longitudinally resolved plasma density profiles exhibit a clear temporal evolution from an initial flat-top to a Gaussian-like shape in the first microseconds as material is ejected out from the capillary, deviating from the often-desired flat-top profile. For plasma with densities of 0.5-$2.5\times 10^{17}$ cm$^{-3}$, temperatures of 1-7 eV were indirectly measured. These measurements pave the way for highly detailed parameter tuning in plasma sources for particle accelerators and beam optics.