Time-dependent density functional theory applied to average atom opacity

被引:9
作者
Gill, N. M. [1 ]
Fontes, C. J. [1 ]
Starrett, C. E. [1 ]
机构
[1] Los Alamos Natl Lab, POB 1663, Los Alamos, NM 87545 USA
来源
PHYSICAL REVIEW E | 2021年 / 103卷 / 04期
基金
美国能源部;
关键词
OPTICAL-PROPERTIES; LINEAR-RESPONSE; PLASMAS; MODEL; PHOTOABSORPTION; ABSORPTION; TARTARUS;
D O I
10.1103/PhysRevE.103.043206
中图分类号
O35 [流体力学]; O53 [等离子体物理学];
学科分类号
070204 ; 080103 ; 080704 ;
摘要
We focus on studying the opacity of iron, chromium, and nickel plasmas at conditions relevant to experiments carried out at Sandia National Laboratories [J. E. Bailey et al., Nature (London) 517, 56 (2015)]. We calculate the photoabsorption cross sections and subsequent opacity for plasmas using linear-response time-dependent density functional theory (TD-DFT). Our results indicate that the physics of channel mixing accounted for in linear-response TD-DFT leads to an increase in the opacity in the bound-free quasicontinuum, where the Sandia experiments indicate that models underpredict iron opacity. However, the increase seen in our calculations is only in the range of 5%-10%. Further, we do not see any change in this trend for chromium and nickel. This behavior indicates that channel mixing effects do not explain the trends in opacity observed in the Sandia experiments.
引用
收藏
页数:10
相关论文
共 46 条
  • [1] A higher-than-predicted measurement of iron opacity at solar interior temperatures
    Bailey, J. E.
    Nagayama, T.
    Loisel, G. P.
    Rochau, G. A.
    Blancard, C.
    Colgan, J.
    Cosse, Ph.
    Faussurier, G.
    Fontes, C. J.
    Gilleron, F.
    Golovkin, I.
    Hansen, S. B.
    Iglesias, C. A.
    Kilcrease, D. P.
    MacFarlane, J. J.
    Mancini, R. C.
    Nahar, S. N.
    Orban, C.
    Pain, J-C.
    Pradhan, A. K.
    Sherrill, M.
    Wilson, B. G.
    [J]. NATURE, 2015, 517 (7532) : 56 - U120
  • [2] Iron-plasma transmission measurements at temperatures above 150 eV
    Bailey, J. E.
    Rochau, G. A.
    Iglesias, C. A.
    Abdallah, J., Jr.
    MacFarlane, J. J.
    Golovkin, I.
    Wang, P.
    Mancini, R. C.
    Lake, P. W.
    Moore, T. C.
    Bump, M.
    Garcia, O.
    Mazevet, S.
    [J]. PHYSICAL REVIEW LETTERS, 2007, 99 (26)
  • [3] TIME-DEPENDENT KOHN-SHAM DENSITY-FUNCTIONAL THEORY
    BARTOLOTTI, LJ
    [J]. PHYSICAL REVIEW A, 1982, 26 (04): : 2243 - 2244
  • [4] On the linear dynamic response of average atom in plasma
    Blenski, T
    [J]. JOURNAL OF QUANTITATIVE SPECTROSCOPY & RADIATIVE TRANSFER, 2006, 99 (1-3) : 84 - 101
  • [5] Dynamic linear response of atoms in plasmas and photo-absorption cross-section in the dipole approximation
    Caizergues, C.
    Blenski, T.
    Piron, R.
    [J]. HIGH ENERGY DENSITY PHYSICS, 2016, 18 : 7 - 13
  • [6] A NEW GENERATION OF LOS ALAMOS OPACITY TABLES
    Colgan, J.
    Kilcrease, D. P.
    Magee, N. H.
    Sherrill, M. E.
    Abdallah, J., Jr.
    Hakel, P.
    Fontes, C. J.
    Guzik, J. A.
    Mussack, K. A.
    [J]. ASTROPHYSICAL JOURNAL, 2016, 817 (02)
  • [7] Dirac PAM, 1930, P CAMB PHILOS SOC, V26, P376
  • [8] CALCULATIONS OF PHOTOABSORPTION BY ATOMS USING A LINEAR RESPONSE METHOD
    DOOLEN, G
    LIBERMAN, DA
    [J]. PHYSICA SCRIPTA, 1987, 36 (01): : 77 - 79
  • [9] Density effects on electronic configurations in dense plasmas
    Faussurier, Gerald
    Blancard, Christophe
    [J]. PHYSICAL REVIEW E, 2018, 97 (02)
  • [10] Mean-force scattering potential for calculating optical properties of dense plasmas
    Gill, N. M.
    Starrett, C. E.
    [J]. HIGH ENERGY DENSITY PHYSICS, 2019, 31 : 24 - 30
12345