Electron impact excitation cross section calculations of the fine structure transitions of Mo and their applications in the diagnostics of the laser induced Mo plasma

Suresh, Indhu; SRIKAR, PS NAGA SAI RAGHAVENDRA; Priti, Priti; Srivastava, Rajesh; Gangwar, Reetesh Kumar

doi:10.1088/1361-6595/ac9081

Cited by 5 publications

(3 citation statements)

References 31 publications

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“…While acknowledging that non-perturbative methods like Convergent Close Coupling (CCC) and B-spline R-Matrix (BSR) may offer enhanced accuracy in the low energy threshold regime, our extensive work in numerous atomic systems attests to the success of our RDW method employing a multi-configurational wavefunction approach. This method has consistently yielded reliable data for plasma modeling applications in the past [17][18][19]. Furthermore, it is acknowledged that cross sections from non-perturbative approaches are often limited and predominantly available in the low energy domain.…”

Section: Introductionmentioning

confidence: 99%

Fine structure resolved excitation cross sections of singly ionized Ga for the modeling and diagnostics of Ga plasmas

Suresh,

Priti,

Srivastava

et al. 2024

Plasma Sources Sci. Technol.

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Calculation of electron impact excitation cross sections for singly charged Ga ions plays a crucial role in plasma modeling, facilitating the comprehension of plasma behavior, characteristics, and dynamics in diverse domains, such as astrophysics, fusion research, the semiconductor industry, etc. In the available literature, there is a notable scarcity of, or even a complete absence of, these cross sections. Hence, in the present work, electron impact excitation cross sections are calculated for the transitions from the fine structure resolved energy levels of the configurations 4s2 and 4s4p to the fine structure resolved energy levels of the configurations 4s4p, 4s5s, 4p2 and 4s4d of the singly charged Ga ion (Ga+) using the relativistic distorted wave approximation theory with the target states represented by multi configurational Dirac Fock wavefunctions. The cross sections are calculated for projectile electron energy varying from threshold to 500 eV. Furthermore, the electron impact excitation rate coefficients for all the transitions under investigation are also calculated for electron temperatures ranging from 0.5 to 5 eV. In addition, analytic fitting of the rate coefficients is also performed, providing a practical resource for directly utilizing in plasma modeling applications.

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Section: Introductionmentioning

confidence: 99%

Fine structure resolved excitation cross sections of singly ionized Ga for the modeling and diagnostics of Ga plasmas

Suresh,

Priti,

Srivastava

et al. 2024

Plasma Sources Sci. Technol.

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“…However, even a minor deviation from the LTE condition can significantly affect the accuracy of the OES results and hence the plasma diagnostics. Thus, OES measurements will only give accurate results when coupled with appropriate population-kinetic models such as collisional radiative (CR) models [12]. These models solve a coupled rate balance equation for the excited state population of the plasma which requires vast atomic and molecular data such as transition energies, oscillator strengths, transition probabilities, and cross sections for various atomic and molecular processes inside the plasma.…”

Section: Introductionmentioning

confidence: 99%

“…Since electron collisions with tin are one of the most dominant processes in LIPs and fusion plasmas, the requirement of EIE cross section data is in high demand. Recently, our group reported the relativistic EIE cross sections for Mo and successfully implemented them in a collisional radiative model for the diagnostics of the LIP of Mo [12].…”

Section: Introductionmentioning

confidence: 99%

Relativistic calculation of electron impact excitation of tin: cross sections of importance in plasma modeling

Suresh

SRIKAR

Priti

et al. 2023

Plasma Sources Sci. Technol.

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The present work includes the calculation of electron impact excitation cross sections for the fine structure resolved transitions in Sn I and Sn II, using relativistic distorted wave approximation with the aid of Dirac–Fock multiconfigurational wavefunctions. For Sn I, the cross sections are calculated for the excitations from the fine structure resolved energy levels of the manifolds, 5s25p2, 5p6s, 5p5d, and 5p6p including the ground state, 5s25p2(3P0) to the fine structure resolved levels of 5s25p2, 5p6[s, p, d, f], 5p4f, 5p5[d, f, g], and 5p7[s, p, d, f] manifolds for a wide range of projectile electron energy from 0 to 500 eV. Further, the cross sections are also calculated for the excitations of Sn II from the fine structure resolved energy levels of the manifolds, 5s25p, 5s5p2, 5s26s, 5s25d and 5s26p including the ground state, 5s25p(2P1/2) to the fine structure resolved levels of 5s5p2, 5s26[s, p, d], 5s25d, 5s27[s, p, d], and 5s28[s, p, d] manifolds. All the cross sections for Sn I except for the excitation from the ground state 5s25p2(3P0) to the fine-structure resolved excited states of 5s25p2, 5p6[s, p] and 5p5d manifolds and all the cross sections for Sn II are reported for the first time. In order to ensure the consistency of the present calculations, a comparison of the oscillator strengths and transition probabilities is carried out with the available calculations and measurements. The present cross sections are also compared with the previous calculations and observed in reasonable agreement. The calculated cross sections are of great interest in the modeling and diagnostic of various plasmas such as laser induced plasma, fusion plasma, etc. Further to ease the use of calculated cross sections, the analytic fitting of the cross sections is also provided.

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Fully relativistic distorted wave calculations of electron impact excitation of gallium atom: Cross sections relevant for plasma kinetic modeling

Suresh,

Priti,

Srivastava

et al. 2024

Spectrochimica Acta Part B: Atomic Spectroscopy

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Electron impact excitation cross section calculations of the fine structure transitions of Mo and their applications in the diagnostics of the laser induced Mo plasma

Cited by 5 publications

References 31 publications

Fine structure resolved excitation cross sections of singly ionized Ga for the modeling and diagnostics of Ga plasmas

Fine structure resolved excitation cross sections of singly ionized Ga for the modeling and diagnostics of Ga plasmas

Relativistic calculation of electron impact excitation of tin: cross sections of importance in plasma modeling

Fully relativistic distorted wave calculations of electron impact excitation of gallium atom: Cross sections relevant for plasma kinetic modeling

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