Ionization balance measurements in low-Z materials by x-ray scattering

We have measured the ionization balance of carbon/beryllium plasmas by covering both the weakly ionized and the nearly fully ionized regimes. The plasma was created by either irradiation with x-rays or direct heating with laser beams at the Omega laser facility. Using as a probe the 4.75 keV (9.0 keV) He-$\alpha $ line radiation produced by simultaneously irradiating a Ti (Zn) foil, we have recorded time-resolved spectrally dispersed scattered spectra with a high efficiency graphite Bragg crystal coupled to a framing camera. Measured values for the plasma temperature and ionization state were obtained by fitting Doppler-broadened and Compton red-shifted scattered spectra at various times after the end of the laser heating. The underlying correlations induced by a solid-state lattice at low temperature are also included in the analysis by comparison with experimental scattering spectra obtained at the Advanced Light Source on cold samples. Comparisons with radiation-hydrodynamics codes are presented.