Recent progress in atomic and molecular physics for controlled fusion and astrophysics

Weber Stefan; Wu Yong; Wang Jianguo

doi:10.1063/5.0045218

Volume 6 Issue 2

Mar. 2021

Turn off MathJax

Article Contents

Article Navigation > Matter and Radiation at Extremes > 2021 > 6(2): 023002

Weber Stefan, Wu Yong, Wang Jianguo. Recent progress in atomic and molecular physics for controlled fusion and astrophysics[J]. Matter and Radiation at Extremes, 2021, 6(2): 023002. doi: 10.1063/5.0045218

Citation:

Weber Stefan, Wu Yong, Wang Jianguo. Recent progress in atomic and molecular physics for controlled fusion and astrophysics[J]. Matter and Radiation at Extremes, 2021, 6(2): 023002. doi: 10.1063/5.0045218

Citation:

PDF( 588 KB)

Recent progress in atomic and molecular physics for controlled fusion and astrophysics

doi: 10.1063/5.0045218

Weber Stefan¹,
Wu Yong^{2, 3},
Wang Jianguo^{2
,
,}

1.
Department of Plasma Physics and Ultra-High Intensity Interaction, ELI-Beamlines Center, Institute of Physics, Czech Academy of Sciences, Za Radnici 835, 25241, Dolní Břežany, Czech Republic
2.
Institute of Applied Physics and Computational Mathematics, 100088 Beijing, China
3.
Center for Applied Physics and Technology, HEDPS, Peking University, 100871 Beijing, China

More Information

Corresponding author: a)Author to whom correspondence should be addressed: wang_jianguo@iapcm.ac.cn
Received Date: 2021-01-24
Accepted Date: 2021-01-27

Available Online: 2021-03-01

Publish Date: 2021-03-15

Abstract

FullText(HTML)

References(11)

References

[1]	J. A. Gaffney et al., “A review of equation-of-state models for inertial confinement fusion materials,” High Energy Density Phys 28, 7–24 (2018).10.1016/j.hedp.2018.08.001
[2]	F. B. Rosmej, V. A. Astapenko, and V. A. Lisitsa, Plasma Atomic Physics, Springer Series on Atomic, Optical, and Plasma Physics Vol. 104, 1st ed. (Springer Publisher, 2020), ISBN-13: 978-3030059668.
[3]	D. Kang, Y. Hou, Q. Zeng, and J. Dai, “Unified first-principles equation of states of deuterium-tritium mixtures in the global inertial confinement fusion region,” Matter Radiat. Extremes 5, 055401 (2020).10.1063/5.0008231
[4]	D. Kang, K. Luo, K. Runge, and S. B. Trickey, “Two-temperature warm dense hydrogen as a test of quantum protons driven by orbital-free density functional theory electronic forces,” Matter Radiat. Extremes 5, 064403 (2020).10.1063/5.0025164
[5]	M. F. Ciappina, E. E. Peganov, and S. V. Popruzhenko, “Focal-shape effects on the efficiency of the tunnel-ionization probe for extreme laser intensities,” Matter Radiat. Extremes 5, 044401 (2020).10.1063/5.0005380
[6]	S. Ryazantsev, I. Skobelev, E. Filippov et al., “Precise wavelength measurements of Potassium He- and Li-like satellites in a laser plasma of a mineral target,” Matter Radiat. Extremes 6, 014402 (2020).10.1063/5.0019496
[7]	S.-X. Wang and L.-F. Zhu, “Non-resonant inelastic X-ray scattering spectroscopy: A momentum probe to detect the electronic structures of atoms and molecules,” Matter Radiat. Extremes 5, 054201 (2020).10.1063/5.0011416
[8]	F. B. Rosmej, V. A. Astapenko, V. S. Lisitsa, and L. A. Vainshtein, “Dielectronic recombination in non-LTE plasmas,” Matter Radiat. Extremes 5, 0642012 (2020).10.1063/5.0014158
[9]	F. B. Rosmej, L. A. Vainshtein, V. A. Astapenko, and V. S. Lisitsa, “Statistical and quantum photoionization cross sections in plasmas: Analytical approaches for any configurations including inner shells,” Matter Radiat. Extremes 5, 064202 (2020).10.1063/5.0022751
[10]	J. Gao, Z. Hu, Y. Wu et al., “Projectile and target excitation in He+ + He collisions at intermediate energies,” Matter Radiat. Extremes 6, 014404 (2021).10.1063/5.0025623
[11]	R. K. Janev, S. Zhang, and J. Wang, “Review of quantum collision dynamics in Debye plasmas,” Matter Radiat. Extremes 1, 237 (2016).10.1016/j.mre.2016.10.002