This paper studies the projectile electron loss cross sections of C^3+ colliding with atomic hydrogen in the frame work of extended over-barrier model at intermediate velocities (25 keV/u-600 keV/u). The electron l...This paper studies the projectile electron loss cross sections of C^3+ colliding with atomic hydrogen in the frame work of extended over-barrier model at intermediate velocities (25 keV/u-600 keV/u). The electron loss is calculated in terms of the interaction between the screened target nucleus and the active projectile electron and of the interaction between projectile electron and target electron. Compared with the convergent close-coupling calculations, screening and anti-screening calculations, this model satisfactorily reproduces the experimentally obtained energy dependence of the electron-impact ionisation cross sections and the single electron loss cross sections over the energy range investigated here.展开更多
We investigate the single-electron loss processes of light charged ions (Li^1+,2+, C^2+,3+,5+, and O^2+,3+) in collisions with helium. To better understand the experimental results, we propose a theoretical m...We investigate the single-electron loss processes of light charged ions (Li^1+,2+, C^2+,3+,5+, and O^2+,3+) in collisions with helium. To better understand the experimental results, we propose a theoretical model to calculate the cross section of projectile electron loss. In this model, an ionization radius of the incident ion was defined under the classical over-barrier model, and we developed "strings" to explain the processes of projectile electron loss, which is similar with the molecular over-barrier model. Theoretical calculations are in good agreement with the experimental results for the cross section of single-electron loss and the ratio of double-to-single ionization of helium associated with one-electron loss.展开更多
基金supported by the National Natural Science Foundation of China (Grant Nos.10975113 and 10675096)
文摘This paper studies the projectile electron loss cross sections of C^3+ colliding with atomic hydrogen in the frame work of extended over-barrier model at intermediate velocities (25 keV/u-600 keV/u). The electron loss is calculated in terms of the interaction between the screened target nucleus and the active projectile electron and of the interaction between projectile electron and target electron. Compared with the convergent close-coupling calculations, screening and anti-screening calculations, this model satisfactorily reproduces the experimentally obtained energy dependence of the electron-impact ionisation cross sections and the single electron loss cross sections over the energy range investigated here.
基金Project supported by the Special Program for Key Basic Research of the Ministry of Science and Technology,China(Grant No.2002CCA00900)the Fundamental Research Funds for the Central Universities of Ministry of Education of China(Grant No.lzujbky-2013-5)
文摘We investigate the single-electron loss processes of light charged ions (Li^1+,2+, C^2+,3+,5+, and O^2+,3+) in collisions with helium. To better understand the experimental results, we propose a theoretical model to calculate the cross section of projectile electron loss. In this model, an ionization radius of the incident ion was defined under the classical over-barrier model, and we developed "strings" to explain the processes of projectile electron loss, which is similar with the molecular over-barrier model. Theoretical calculations are in good agreement with the experimental results for the cross section of single-electron loss and the ratio of double-to-single ionization of helium associated with one-electron loss.
