On the determination of radial matrix elements for high-<i>n</i>transitions in hydrogenic atoms and ions

Hey, John D.

doi:10.1088/0953-4075/39/12/003

Cited by 36 publications

(119 citation statements)

References 58 publications

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“…The study of recombination transitions requires the evaluation of matrix elements of operator R between states with high principal quantum number n. This is impossible when n 50 (see Hey 2006 for a numerical solution of this problem).…”

Section: Initial Expressionsmentioning

confidence: 99%

“…Now we use the recurrence relations for the radial integrals obtained by Infeld & Hull (1951) (see also Hey (2006)), that are shown here:…”

Section: Appendix A: Calculation Of the Width Operatormentioning

confidence: 99%

“…To our knowledge, these discrepancies remain and have even been qualified as "mysterious" (Griem 2005;Watson 2006) 1 . In this context, approximate expressions are required to calculate transition probabilities between states with very high principal quantum numbers (n > 100) (Watson 2006;Hey 2006). This need rises because, although the analytical expressions of those transitions probabilites are known (Gordon 1929;Bethe & Salpeter 1957), they are not computationally manageable due to the large value of the factorials involved.…”

Section: Introductionmentioning

confidence: 99%

“…This need rises because, although the analytical expressions of those transitions probabilites are known (Gordon 1929;Bethe & Salpeter 1957), they are not computationally manageable due to the large value of the factorials involved. In recent works (Watson 2006;Hey 2006) recurrence relations have been used to obtain transition probabilities that are much easier to evaluate. The investigation can be carried out in this way for high values of n; although, as recognised by one of the authors (Watson 2006), the mystery of the discrepancy with the experiments cannot be solved with those approximate expressions.…”

Section: Introductionmentioning

confidence: 99%

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Exact expression of the impact broadening operator for hydrogen Stark broadening

Ma¹,

González

Talin³

et al. 2007

A&A

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Aims. Recent measurements on the Stark broadening of radio recombination lines show values and trends in disagreement with conventional theories. Different attemps to explain those disagreements have not been successfull for any of the employed theoretical models. In particular, the impact model that describes well the physical conditions at which the studied broadenings occur, shows a functional trend upon the principal quantum number of the studied transitions that does not correspond to the experimental observations. Methods. High values of the principal quantum number require computable formulas for the calculation of transition probabilities. Some of those expressions have been published, leading to approximate formulas on the dependence of the line width versus the principal quantum number of the upper level of the transition. Results. In this work an exact expression for the hydrogen Stark width in the frame of impact approximation is given.

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Section: Initial Expressionsmentioning

confidence: 99%

“…Now we use the recurrence relations for the radial integrals obtained by Infeld & Hull (1951) (see also Hey (2006)), that are shown here:…”

Section: Appendix A: Calculation Of the Width Operatormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Exact expression of the impact broadening operator for hydrogen Stark broadening

Ma¹,

González

Talin³

et al. 2007

A&A

View full text Add to dashboard Cite

show abstract

“…(2) using an 11-point Newton-Cotes method, where the radial matrix elements g(n, l, κ, l ′ ) were obtained using the recursion relation given by Burgess [32]. Einstein A-coefficients were computed by using the recursion relations obtained by Hey [40] for the radial matrix elements R nl n ′ l ′ . Finally, we obtained the probabilities P i K using a sparse matrix technique similar to that of Ref.…”

Section: A Computation Of the Effective Ratesmentioning

confidence: 99%

Ultrafast effective multilevel atom method for primordial hydrogen recombination

Ali-Haı̈moud

Hirata

2010

Phys. Rev. D

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Cosmological hydrogen recombination has recently been the subject of renewed attention because of its importance for predicting the power spectrum of cosmic microwave background anisotropies. It has become clear that it is necessary to account for a large number n 100 of energy shells of the hydrogen atom, separately following the angular momentum substates in order to obtain sufficiently accurate recombination histories. However, the multi-level atom codes that follow the populations of all these levels are computationally expensive, limiting recent analyses to only a few points in parameter space. In this paper, we present a new method for solving the multi-level atom recombination problem, which splits the problem into a computationally expensive atomic physics component that is independent of the cosmology, and an ultrafast cosmological evolution component. The atomic physics component follows the network of bound-bound and bound-free transitions among excited states and computes the resulting effective transition rates for the small set of "interface" states radiatively connected to the ground state. The cosmological evolution component only follows the populations of the interface states. By pre-tabulating the effective rates, we can reduce the recurring cost of multi-level atom calculations by more than 5 orders of magnitude. The resulting code is fast enough for inclusion in Markov Chain Monte Carlo parameter estimation algorithms. It does not yet include the radiative transfer or high-n two-photon processes considered in some recent papers. Further work on analytic treatments for these effects will be required in order to produce a recombination code usable for Planck data analysis.

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New clues to the impact broadening mystery in radio recombination lines

Bell

2011

Astrophys Space Sci

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Problems where impact broadened radio recombination lines appeared narrower than predicted first showed up ∼ 40 years ago at frequencies below ∼ 3 GHz. But it was soon found that the observations could be explained by throwing out the uniform density models and replacing them with variable density ones. However, this problem re-appeared recently when a mysterious line narrowing above quantum numbers of (n, ∆n) = (202,8) was reported from sensitive observations of Orion and W51 near 6 GHz. Here it is demonstrated that the narrowing is unlikely to be caused by the data processing technique and therefore must be source related. It is further demonstrated that the observed line narrowing can be tied to one of the fundamental properties of radio recombination lines; namely the fact that the spacing of adjacent n-transitions increases with frequency. The line narrowing is observed to begin when the n-transition density, D n , exceeds ∼ 11.6 transitions per GHz. This may imply that it is somehow related either to a previously overlooked effect in the impact broadening process, or to some unknown parallel process, that is tied to the separation between adjacent n-transitions. Based on these results it can be concluded, as has also been concluded in several theoretical investigations, that the observed line narrowing is not tied to a fixed range of either n or ∆n.

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On the determination of radial matrix elements for high-ntransitions in hydrogenic atoms and ions

Cited by 36 publications

References 58 publications

Exact expression of the impact broadening operator for hydrogen Stark broadening

Exact expression of the impact broadening operator for hydrogen Stark broadening

Ultrafast effective multilevel atom method for primordial hydrogen recombination

New clues to the impact broadening mystery in radio recombination lines

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