FLYCHK: Generalized population kinetics and spectral model for rapid spectroscopic analysis for all elements

Chung, H.‐K.; Chen, M H.; Morgan, W. L.; Ralchenko, Yuri; Lee, R W.

doi:10.1016/j.hedp.2005.07.001

Cited by 618 publications

(387 citation statements)

References 30 publications

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“…For autoionization rates, we use the method of Chung et al [27]. These rates involve three states -the autoionizing state n, plus the lower and upper states i,j from the next ionized isosequence that provide a stabilizing transition.…”

Section: Discussionmentioning

confidence: 99%

“…Bauche et al [26] review autoionization and resonant capture, and discuss approximations for calculating these rates. Here, following the lead of Chung et al [27], we use the formulation developed by Sobel'man et al [28]. As shown in [27], this simple formula reproduces the results of detailed calculations very well.…”

Section: Atomic Model Constructionmentioning

confidence: 91%

“…Here, following the lead of Chung et al [27], we use the formulation developed by Sobel'man et al [28]. As shown in [27], this simple formula reproduces the results of detailed calculations very well. This result, combined with the ability to generate an atomic structure that includes autoionizing states, is perhaps the key piece in inexpensively calculating ionization balance for complex atoms.…”

Section: Atomic Model Constructionmentioning

confidence: 91%

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Advances in NLTE modeling for integrated simulations

Scott

Hansen

2010

High Energy Density Physics

192

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The last few years have seen significant progress in constructing the atomic models required for non-local thermodynamic equilibrium (NLTE) simulations. Along with this has come an increased understanding of the requirements for accurately modeling the ionization balance, energy content and radiative properties of different elements for a wide range of densities and temperatures. Much of this progress is the result of a series of workshops dedicated to comparing the results from different codes and computational approaches applied to a series of test problems. The results of these workshops emphasized the importance of atomic model completeness, especially in doubly excited states and autoionization transitions, to calculating ionization balance, and the importance of accurate, detailed atomic data to producing reliable spectra.We describe a simple screened-hydrogenic model that calculates NLTE ionization balance with surprising accuracy, at a low enough computational cost for routine use in radiation-hydrodynamics codes. The model incorporates term splitting, n=0 transitions, and approximate UTA widths for spectral calculations, with results comparable to those of much more detailed codes. Simulations done with this model have been increasingly successful at matching experimental data for laser-driven systems and hohlraums.Accurate and efficient atomic models are just one requirement for integrated NLTE simulations. Coupling the atomic kinetics to hydrodynamics and radiation transport constrains both discretizations and algorithms to retain energy conservation, accuracy and stability. In particular, the strong coupling between radiation and populations can require either very short timesteps or significantly modified radiation transport algorithms to account for NLTE material response. Considerations such as these continue to provide challenges for NLTE simulations.

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Section: Discussionmentioning

confidence: 99%

Section: Atomic Model Constructionmentioning

confidence: 91%

Section: Atomic Model Constructionmentioning

confidence: 91%

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Advances in NLTE modeling for integrated simulations

Scott

Hansen

2010

High Energy Density Physics

192

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show abstract

“…This model determines the energy levels of an electronic configuration as a sum of hydrogenic one-electron energies that are computed with appropriate screened nuclear charges. The SHM used in the average ion model context provides electronic populations with good accuracy and it also allows computing radiative properties [1][2][3][4][5][6][7][8] such as the opacity or the emissivity, as well as thermodynamic properties such as the equation of state or the shock Hugoniot curves [9][10][11]. For this reason the model has been widely used in the simulation of inertial confinement fusion [12].…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless, some authors take them into account using the hydrogenic approximation with relativistic corrections [7,8], and others, use Dirac's relativistic energy expression for the hydrogen atom for the same purpose [1,20]. However, currently there does not exist a set of screening constants fit to energy values considering j-splitting.…”

Section: Introductionmentioning

confidence: 99%

A new set of relativistic screening constants for the screened hydrogenic model

Mendoza¹,

Rubiano²,

Gil³

et al. 2011

High Energy Density Physics

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Keywords:Screening constants Screened hydrogenic model A new Relativistic Screened Hydrogenic Model has been developed to calculate atomic data needed to compute the optical and thermodynamic properties of high energy density plasmas. The model is based on a new set of universal screening constants, including nij-splitting that has been obtained by fitting to a large database of ionization potentials and excitation energies. This database was built with energies compiled from the National Institute of Standards and Technology (NIST) database of experimental atomic energy levels, and energies calculated with the Flexible Atomic Code (FAC). The screening constants have been computed up to the 5p¡/2 subshell using a Genetic Algorithm technique with an objective function designed to minimize both the relative error and the maximum error. To select the best set of screening constants some additional physical criteria has been applied, which are based on the reproduction of the filling order of the shells and on obtaining the best ground state configuration. A statistical error analysis has been performed to test the model, which indicated that approximately 88% of the data lie within a ±10% error interval. We validate the model by comparing the results with ionization energies, transition energies, and wave functions computed using sophisticated self-consistent codes and experimental data.

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Composition of Partially Ionized Systems Using the PlanckLarkin Partition Function of Mid‐Z ions

Sengebusch¹,

Reinholz

Röpke

2009

Contrib. Plasma Phys.

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We report on the composition of warm, dense plasmas of M-shell ions. Assuming local thermal equilibrium, the abundance of different ionization stages is given by a set of coupled Saha-equations. In order to avoid discontinuities at the Mott density, the partition functions have to account for pressure ionization due to continuum lowering consistently. The Planck-Larkin renormalization of bound and scattering states is well elaborated for hydrogenic systems. This paper shows the consistent extension to moderately ionized Mid-Z elements. We present results for solid-density polymere and titanium plasmas.

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FLYCHK: Generalized population kinetics and spectral model for rapid spectroscopic analysis for all elements

Cited by 618 publications

References 30 publications

Advances in NLTE modeling for integrated simulations

Advances in NLTE modeling for integrated simulations

A new set of relativistic screening constants for the screened hydrogenic model

Composition of Partially Ionized Systems Using the PlanckLarkin Partition Function of Mid‐Z ions

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