Abstract
Ion energy distributions arising from laser-produced plasmas of Sn are measured over a wide laser parameter space. Planar-solid and liquid-droplet targets are exposed to infrared laser pulses with energy densities between 1 J cm−2 and 4 kJ cm−2 and durations spanning 0.5 ps to 6 ns. The measured ion energy distributions are compared to two self-similar solutions of a hydrodynamic approach assuming isothermal expansion of the plasma plume into vacuum. For planar and droplet targets exposed to ps-long pulses, we find good agreement between the experimental results and the self-similar solution of a semi-infinite simple planar plasma configuration with an exponential density profile. The ion energy distributions resulting from solid Sn exposed to ns-pulses agrees with solutions of a limited-mass model that assumes a Gaussian-shaped initial density profile.
Highlights
Plasma expansion into vacuum is a subject of great interest for many applications ranging from ultracold plasmas [1, 2] over laser acceleration [3, 4] to shortwavelength light sources [5, 6]
For such light sources driven by laser-produced plasmas (LPPs) the optics that collect the plasma-generated light are exposed to particle emission from the plasma
First we present the energy distributions of the Sn ion emission for three different pulse lengths and same energy density of the laser and show that the experimental data can be well described by the selfsimilar solutions of the hydrodynamic model
Summary
Plasma expansion into vacuum is a subject of great interest for many applications ranging from ultracold plasmas [1, 2] over laser acceleration [3, 4] to shortwavelength light sources [5, 6]. For such light sources driven by laser-produced plasmas (LPPs) the optics that collect the plasma-generated light are exposed to particle emission from the plasma. Both droplet and planar targets have been investigated [14, 15] but no unique optimal conditions have been found so far
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