Abstract

Auger-electron emission from 400keV carbon ions excited in single gas collisions with C${\mathrm{H}}_{4}$, Ne, and Ar has been investigated. Prompt and time-delayed projectile electron-emission spectra have been measured, and spectroscopic assignments are given. Absolute inner-shell vacancy-production cross sections and relative line intensities deduced from the prompt and time-delayed spectra for excited carbon ions have been compared as a function of exciter gases. An enhanced probability for electron excitation into high-spin states in carbon is found. Especially for the collision system ${\mathrm{C}}^{+}$\ensuremath{\rightarrow}Ne, a striking population of the $1s2s2p^{4}P^{o}$ quartet state relative to the berylliumlike quintet and boronlike sextet states is observed. It is assumed that this is accounted for by cascade-feeding mechanisms. In particular, cascades from Rydberg levels feeding the $\mathrm{C}\mathrm{IV} 1s2s2p^{4}P^{o}$, $\mathrm{C}\mathrm{III} 1s2s2{p}^{2}^{5}P$, and $\mathrm{C}\mathrm{II} 1s2s2{p}^{3}^{6}S^{o}$ high-spin states are discussed. Finally, wavelengths associated with electric dipole ($E1$) transitions among quintet terms in C III and sextet terms in C II are predicted using $\mathrm{ab}$ initio methods.