Influence of the temporal contrast on the characteristics of laser-produced ultrafast Kα Hard X-ray source

Abstract

Characteristics of the intense ultrafast quazi-monochromatic X-ray source at 17.4 keV generated by a multi-TW femtosecond Ti:Sa-laser beam (λ=800 nm) tightly focused on a thick molybdenum target are investigated within a wide range of laser pulse peak intensities (1016 - 1019 W/cm2) and temporal contrast (106 - 1010). Spatial and absolute spectrally-resolved energetic parameters of produced pulsed X ray emission are measured. Fluxes of Mo Kα line radiation reaching 2× 109 photons/sr per laser shot and energy conversion efficiency as high as 3.2× 10-5 sr-1 are obtained at high laser contrast of >109. The interplay of resonance absorption, vacuum heating and ponderomotive (JxB) heating mechanisms of the laser-plasma interaction is clearly demonstrated by different Kα conversion efficiency dependencies at different laser pulse intensity and contrast parameters. The results are confirmed by examining dependencies on the laser incidence angle. In the relativistic intensity regime, the Kα efficiency shows similar values within the whole examined range of the laser temporal contrast, which varies over 4 orders of magnitude resulting in the electron density scale length L of the pre-formed plasma changing from L<<λ to L>λ. It confirms the dominant role of the JxB mechanism accompanied by the effect of plasma interface steepening under laser radiation pressure in the relativistic interaction regime.