Showing papers by "Muhammad Hassan Sayyad published in 2003"

Absolute photoionization cross sections and resonance structure of doubly ionized silicon in the region of the 2 p − 1 threshold: Experiment and theory

Abstract: We present the absolute photoionization cross section of doubly ionized silicon as a function of photon energy. These were obtained by merging a ${\mathrm{Si}}^{2+}$ ion beam generated in an electron cyclotron resonance source with monochromatized synchrotron radiation from an undulator. The photoion yield measurements were carried out in the photon energy range between 95 eV and 170 eV, i.e., the region corresponding to the excitation followed by the ionization (threshold $\ensuremath{\sim}133.8\mathrm{eV})$ of an inner-subshell $2p$ electron. Resonance structure due to $2p$ excitation in the ${2p}^{6}3s3p{}^{3}P$ metastable state was also observed with its contribution to the total cross section not exceeding 3%. Calculation of the $2p$ photoionization continuum cross section as a function of photon energy was carried out using the relativistic random-phase approximation (RRPA) and agreed very well with the corresponding measurements. The resonance structure in the $3s$ cross section below the $2p$ threshold was found to be in good agreement with the multiconfiguration atomic structure calculations of Sayyad et al. [J. Phys. B 28, 1715 (1995)], while the corresponding RRPA-RMQDT (relativistic multi-channel quantum-defect theory) calculations proved less successful.