Your search keyword '"PLASMA temperature"' showing total 3 results

1. Rate Coefficients for Dielectronic Recombination of Carbon-like 40Ca14+.

Author

Wen, W. Q., Huang, Z. K., Wang, S. X., Khan, N., Wang, H. B., Chen, C. Y., Zhang, C. Y., Preval, S., Badnell, N. R., Ma, W. L., Chen, D. Y., Liu, X., Zhao, D. M., Mao, L. J., Li, J., Ma, X. M., Tang, M. T., Yin, D. Y., Yang, W. Q., and Yuan, Y. J.

Subjects

*ION recombination, *DELOCALIZATION energy, *STORAGE rings, *LOW temperatures, *PLASMA temperature, *CALCIUM ions

Abstract

Dielectronic recombination (DR) rate coefficients for carbon-like 40Ca14+ forming nitrogen-like 40Ca13+ have been measured using the electron–ion merged-beam technique at the heavy-ion storage ring CSRm at the Institute of Modern Physics in Lanzhou, China. The measured DR rate coefficients in the energy range from 0 to 92 eV cover most of the DR resonances associated with 2s22p2 → 2s22p2 and 2s22p2 → 2s2p3 core transitions (ΔN = 0). Theoretical calculations of the DR cross sections were carried out by using two different state-of-the-art atomic theoretical techniques, multiconfiguration Breit–Pauli (MCBP) code AUTOSTRUCTURE and relativistic configuration interaction code FAC, to compare with the experimental rate coefficients. The theoretical calculations agree with the experimental results at collision energy higher than 10 eV. However, significant discrepancies of resonance energies and strengths can be found at collision energy below 8 eV. Temperature-dependent plasma recombination rate coefficients were derived from the measured DR rate coefficients in the energy range from 0.1 to 1000 eV and compared with the recommended atomic data from the literature. The theoretical data of Gu et al. and Zatsarinny et al. are 30% lower than the experimental results at the temperatures of photoionized plasmas, but have a very good agreement at the temperatures of collisionally ionized plasmas. Other previously published theoretical data of Jacobs et al. and Mazzotta et al. by using Burgess formula and LS-coupling calculations significantly underestimate the plasma rate coefficients in the low temperature range. The present results comprise a set of benchmark data suitable for astrophysical modeling. [ABSTRACT FROM AUTHOR]

Published

2020

2. Rate Coefficients for Dielectronic Recombination of Carbon-like 40Ca14+.

Author

Wen, W. Q., Huang, Z. K., Wang, S. X., Khan, N., Wang, H. B., Chen, C. Y., Zhang, C. Y., Preval, S., Badnell, N. R., Ma, W. L., Chen, D. Y., Liu, X., Zhao, D. M., Mao, L. J., Li, J., Ma, X. M., Tang, M. T., Yin, D. Y., Yang, W. Q., and Yuan, Y. J.

Subjects

ION recombination, DELOCALIZATION energy, STORAGE rings, LOW temperatures, PLASMA temperature, CALCIUM ions

Abstract

Dielectronic recombination (DR) rate coefficients for carbon-like 40Ca14+ forming nitrogen-like 40Ca13+ have been measured using the electron–ion merged-beam technique at the heavy-ion storage ring CSRm at the Institute of Modern Physics in Lanzhou, China. The measured DR rate coefficients in the energy range from 0 to 92 eV cover most of the DR resonances associated with 2s22p2 → 2s22p2 and 2s22p2 → 2s2p3 core transitions (ΔN = 0). Theoretical calculations of the DR cross sections were carried out by using two different state-of-the-art atomic theoretical techniques, multiconfiguration Breit–Pauli (MCBP) code AUTOSTRUCTURE and relativistic configuration interaction code FAC, to compare with the experimental rate coefficients. The theoretical calculations agree with the experimental results at collision energy higher than 10 eV. However, significant discrepancies of resonance energies and strengths can be found at collision energy below 8 eV. Temperature-dependent plasma recombination rate coefficients were derived from the measured DR rate coefficients in the energy range from 0.1 to 1000 eV and compared with the recommended atomic data from the literature. The theoretical data of Gu et al. and Zatsarinny et al. are 30% lower than the experimental results at the temperatures of photoionized plasmas, but have a very good agreement at the temperatures of collisionally ionized plasmas. Other previously published theoretical data of Jacobs et al. and Mazzotta et al. by using Burgess formula and LS-coupling calculations significantly underestimate the plasma rate coefficients in the low temperature range. The present results comprise a set of benchmark data suitable for astrophysical modeling. [ABSTRACT FROM AUTHOR]

Published

2020

3. Dielectronic recombination rate coefficients of fluorine-like nickel.

Author

Wang, Shu-Xing, Huang, Zhong-Kui, Wen, Wei-Qiang, Chen, Chong-Yang, Schippers, Stefan, Xu, Xin, Sardar, Shahid, Khan, Nadir, Wang, Han-Bing, Dou, Li-Jun, Mahmood, Sultan, Zhao, Dong-Mei, Zhu, Xiao-Long, Mao, Li-Jun, Ma, Xiao-Ming, Li, Jie, Tang, Mei-Tang, Mao, Rui-Shi, Yin, Da-Yu, and Yuan, You-Jin

Subjects

*ION recombination, *NICKEL, *STORAGE rings, *QUANTUM mechanics, *PLASMA temperature, *LOW temperatures

Abstract

Electron-ion recombination rate coefficients for fluorine-like nickel ions have been measured by employing the merged-beam technique at the cooler storage ring CSRm at the Institute of Modern Physics in Lanzhou, China. The measured spectrum covers the energy range of 0–160 eV, including all the dielectronic recombination (DR) resonances associated with ΔN = 0 core excitations. The DR cross sections in this energy range were calculated by a relativistic configuration interaction method using the flexible atomic code (FAC). Radiative recombination (RR) cross sections were obtained from a modified version of the semi-classical Bethe & Salpeter (1957, Quantum Mechanics of One- and Two-Electron 56 Systems (Springer)) formula for hydrogenic ions. The comparison between the measurement and the calculation shows that the present theoretical model still needs to be improved at low collision energies. Temperature dependent plasma recombination rate coefficients were derived from the measured DR rate coefficients in the temperature range of 103–108 K and compared with the presently calculated result as well as previous available data in the literature. The experimentally derived data agree well with the theoretical calculations for temperatures where Ni19+ ions form in collisionally ionized plasmas. At lower temperatures typical for photo-ionized plasmas, discrepancies are found beyond the experimental uncertainty, which can be attributed to the disagreement between the measurement and the calculation of the low-lying DR resonances. The present experimental result benchmarks the plasma DR rate coefficients, in particular for temperatures below 105 K where the ΔN = 0 DR resonances dominate. [ABSTRACT FROM AUTHOR]

Published

2019