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Article

Calculation of Rates of 4p–4d Transitions in Ar II

CTAMOP, School of Mathematics & Physics, Queen’s University, Belfast BT7 1NN, UK
Submission received: 29 December 2016 / Revised: 27 January 2017 / Accepted: 9 February 2017 / Published: 21 February 2017
(This article belongs to the Special Issue Spectra of Ionized Atoms: From Laboratory to Space)

Abstract

:
Recent experimental work by Belmonte et al. (2014) has given rates for some 4p–4d transitions that are significantly at variance with the previous experimental work of Rudko and Tang (1967) recommended in the NIST tabulations. To date, there are no theoretical rates with which to compare. In this work, we provide such theoretical data. We have undertaken a substantial and systematic configuration interaction calculation, with an extrapolation process applied to ab initio mixing coefficients, which gives energy differences in agreement with experiment. The length and velocity forms give values that are within 10%–15% of each other. Our results are in sufficiently close agreement with those of Belmonte et al. that we can confidently recommend that their results are much more accurate than the early results of Rudko and Tang, and should be adopted in place of the latter.

1. Introduction

Some years ago, we [1,2,3] studied transitions among Ar II levels arising from configurations 3s23p5, 3s3p6, 3p43d, 3p44s, and 3p44p. That work was prompted by a range of conflicting experimental results and a limited amount of theoretical work. We found that our calculations gave transition rates in close agreement with the experimental values recommended by Vujnović and Wiese [4], and gave much closer agreement between length and velocity forms of transition rates than were obtained by the only other major theoretical work, conducted by Luyken [5]. The values cited in the NIST tabulations [6] are taken from Bennett et al. [7] where possible, in agreement with the recommended values given in [4], but for other 4p–4d transitions, it is the data of Rudko and Tang [8] which are quoted.
Recently, Belmonte et al. [9]—building on the work of Aparicio et al. [10]—extended the experimental study to 4p–4d (and a few other) transitions. They also included results for some transitions between the lower-lying levels previously studied in [2,3,4], and found that they were in much closer agreement with the experimental values recommended by Vujnović and Wiese [4], and with our previous calculations, than with other experimental work. By contrast, they found that their results differed by up to a factor of five from the experimental values of Rudko and Tang [8]. The purpose of the present work is to provide some theoretical corroboration (or otherwise) of the new experimental results.

2. Method of Calculation

The calculations in this work have been undertaken using the code CIV3 [11,12].

2.1. Basic Theory

We express the wave functions in terms of configuration interaction (CI) expansions:
Ψ ( J ) = i = 1 M a i Φ i ( α i L i S i J )
where { Φ i } are single-configuration functions (configuration state functions—CSFs) and the expansions in general include summations over L i and S i . For a specific choice of { Φ i } , the expansion coefficients { a i } are the eigenvector components of the diagonalized Hamiltonian with matrix elements H i j = < Φ i | H | Φ j > . In this work, we take the Hamiltonian H to be the Schrödinger Hamiltonian plus the mass correction and Darwin terms, together with a modified spin-orbit term
H s o = 1 2 α 2 i = 1 N Z ζ l r i 3 l i . s i
In (2), the sum is over the electrons, and the parameters { ζ l } depend on the l-value of the electrons involved in the interaction (Hibbert and Hansen 1989) [2].
The ordered eigenvalues { E i } of the Hamiltonian matrix are upper bounds to the similarly-ordered energy levels:
E i E i exact
Hence, any of the eigenvalues may be used as the variational functional for optimisation of the radial parts of the one-electron orbitals from which the { Φ i } are constructed. We express these radial functions as sums of normalised Slater-type orbitals (STOs):
P n l ( r ) = j = 1 k C j n l χ j n l ( r )
where the STOs are of the form
χ j n l ( r ) = ( 2 ξ j n l ) 2 I j n l + 1 ( 2 I j n l ) ! 1 / 2 r I j n l exp ( ξ j n l r )
Being integers, the { I j n l } are kept fixed, but the exponents { ξ j n l } and the coefficients { C j n l } may be treated as variational parameters in (3), subject to the orthonormality conditions:
0 P n l ( r ) P n l ( r ) d r = δ n n ; l < n n

2.2. Radial Function Parameters

Since we were adding to earlier work [3], we were able to use many of the radial functions we used previously. However, that work did not include 4d levels. The radial function parameters are determined by optimising the energy associated with different states; the optimisation is undertaken in LS coupling. The radial function parameters used in this work were optimised as displayed in Table 1. We comment here on the reasons underpinning the choice of procedure used for the functions new to this work.
  • The 6p function was newly introduced in this calculation. While retaining the 4p and 5p functions from previous work, the parameters for 6p were optimised on the ground state to improve the capture of the electron correlation effect in the n = 3 shell, and thereby improve the calculated separation between the ground and excited states.
  • We retained the previous 3d and 4d functions, but reoptimised 5d and 6d. We considered the lowering of the energy of several different states brought about by the introduction of 5d. The effect was largest for the 3p44d 4F state. Similarly, the lowering of the energy of several different doublet states through the introduction of 6d was noted. There was a substantial difference in the mixings between doublet states, depending on the final LS symmetry chosen for the optimisation. As a consequence, we selected those obtained during the optimisation of the 3p4(3P)4d 2D state.
  • We reoptimised the 6s function on the 5s 4P state, since the energy of that state lay in the region of those of the 4d states.
The set of parameters for all the radial functions used here is displayed in Table 2.

2.3. Choice of Configurations

In our previous work [3], we included a limited range of configurations aimed at capturing the main correlation effects in the 3p43d/4s/4p states. This led to some difficulties, primarily that the degree of correlation included in the ground state was substantially greater than for the excited states, and the order of some 3d and 4s levels was incorrect.
Consequently, in this work, we have included all possible configurations that can be obtained by one- and two-orbital replacements from the 3l and 4l subshells to the full set of orbitals shown in Table 2, from the configurations of the following reference sets.
Odd3p5; 3p44p
Even3s3p6; 3p44s, 3p45s, 3p46s; 3p43d, 3p44d, 3p45d, 3p46d
The configurations of the reference sets were those with a significant CI coefficient in a relatively small CI calculation. For each possible LSπ symmetry, all CSFs were then constructed and combined to give a set of CSFs for each allowed J π symmetry, resulting in Hamiltonian matrices of the following sizes.
J = 0.5J = 1.5J = 2.5J = 3.5J = 4.5
Odd13,08218,14417,6039148
Even44,14975,38375,96461,07228,854

2.4. Relativistic Effects

As in our earlier work [3], relativistic effects are included using the Breit–Pauli approximation, retaining in the Hamiltonian the mass correction and Darwin terms and a modified spin-orit term as given in (2). The parameters ζ l —which depend only on the l-value of the electrons—were chosen to give the best fit to matrix elements of the full spin-orbit plus spin-other-orbit operators with respect to key CSFs. This led to the values 0.0, 0.856, 1.0, 1.0 for l = 0, 1, 2, 3, respectively. The d- and f-orbitals contribute little to the fine structure, most of which comes from configurations containing 3p4(3P).

3. Results

In our earlier work [3], we found that our choice of configurations resulted in the ground state being around 12,000 cm−1 too low when compared with the excited states. In the present work, with our more systematic choice of configurations, we find that our ab initio energy separations are in much better agreement with the experimental work of Minnhagen [14] and Saloman [15], given in the tabulations of NIST [6]. Most of the energy separations agree to within 1000 cm−1 with these experimental results, the exceptions being a few of the levels associated with states containing a 3p4 1D core (within 3000 cm−1) and those of 3p4 1S 3d (about 4000 cm−1). Moreover, the difficulty we encountered earlier with a very strong mixing between the 3p4(1D)4s and 3p4(3P)3d 2 D 3 / 2 levels is now sufficiently removed to clearly define the lower of the two as belonging to the 4s state, in agreement with experiment.
Before calculating the electric dipole transition rates between all these levels, we refined the CI mixing coefficients by making small adjustments to some diagonal elements of the Hamiltonian matrices, and then rediagonalising the adjusted matrices. In this way, we were able to bring the calculated eigenvalue differences into agreement with the experimental energy separations. From past experience, we have found that, while the mixing coefficients are improved by this process, there is a tendency for the coefficients to be somewhat over-corrected. However, since most of the matrix corrections are quite small, and many of the levels are spectroscopically fairly pure, the principal effect of this fine-tuning process will be to allow the use of experimental energy separations, with some modifications to the interactions between levels in a limited number of cases.
In Table 3, we present our calculated transition rates in both length and velocity gauges for those 4p–4d transitions for which experimental values are given by [9]. The corresponding results from the experimental determinations of [7,8] are also listed. Belmonte et al. [9] also give estimates of the uncertainties in their results, which they obtain not only from the customary standard deviation of experimental measurements, but also from a detailed and careful analysis of a range of other factors which could lead to uncertainties. As a result of this analysis, they are able to provide uncertainties, most of which lie in the 10%–20% range, with a small proportion having higher uncertainties. Table 3 quotes those uncertainties.

4. Discussion

The accuracy of theoretical energy differences and transition rates can only be estimated: there is no monotonic convergence of these quantities, even as the wave functions are systematically improved. Instead, it is necessary to refer to a number of indicators of accuracy, as explained in [16]. These indicators include a comparison between calculated and experimental energy levels, the convergence of results as the wave functions are improved, the degree of agreement between different forms of the transition rates (typically length and velocity), comparison with other calculations, and of course, comparison with experiment.
In this work, we have adopted our fine-tuning process, which ensures that we are using accurate transition energies and that the CI mixing coefficients are as accurate as we can obtain within the limitations of our finite configuration lists. We have not undertaken a sequence of calculations of different complexity, as would be necessary if we were to establish the degree of convergence of the results, but as many of the levels are fairly pure spectroscopically, we do not believe that this would have a major influence on the level of accuracy achieved. There are no other theoretical transition rates available in the literature for these transitions. That leaves two major factors to be taken into account in assessing the accuracy of our calculations.
It can be observed from Table 3 that the length and velocity forms of our calculated transition rates differ fairly consistently by about 10%–15%, the length form mostly giving the larger of the two. This discrepancy is an indication of either insufficient treatment of electron correlation in the 3p4 core, or (given the strong state-dependency of the valence orbitals) insufficient flexibility in the form of the radial functions of the valence orbitals; that is, there may be too few basis functions in the expansions (4).
However, in spite of these limitations, the important thing to note is the comparison between our calculated A-values and the experimental values recently determined by Belmonte et al. [9]. For most transitions listed in Table 3, our results lie quite close to the experimental values of [9], bearing in mind the uncertainty of both sets of results. Similar good agreement is found with the experimental results of [7], which are the values recommended in the critical compilation of [4]. By contrast, the experimental results of Rudko and Tang [8] are substantially different from both the recent experimental values and our calculations.
In view of these considerations, we would anticipate that for most of the transitions listed in Table 3, our results are accurate to about 20%–25%, or better.

5. Conclusions

We have undertaken a substantial calculation of 4p–4d transitions in Ar II, using a systematic configuration interaction process. These results provide the only theoretical corroboration with which the recent experimental results given in [9] and in other earlier work may be compared. It is clear that our calculations substantially support the results of Belmonte et al. [9], and of Bennett et al. [7] (where comparison is possible), but are in substantial disagreement with the experimental data of Rudko and Tang [8] for many of the transitions considered here. However, until the recent work of [9], the only available data for the doublet transitions was that of [8], and for those transitions, it is the values of [8] which are quoted in the NIST tabulations [6]. We therefore recommend that—where possible—the transition rates of [9] are adopted instead.

Conflicts of Interest

The author declares no conflict of interest.

References

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Table 1. Method of determining the radial functions.
Table 1. Method of determining the radial functions.
OrbitalProcess of Optimisation
1s, 2s, 2p, 3sHartree–Fock orbitals of 3p4 1D of Ar III
(Clementi and Roetti (1974)) [13]
3pExponents taken from the Hartree–Fock orbital of 3p4 1D
of Ar III; coefficients reoptimised on 3p44s 4P of Ar II
Eigenvalue minimisedConfigurations
3d3s3p6 2S3s3p6, 3s23p43d
4s3p44s 4P3p44s
4p3p44p 4Do3p44p
4d3p43d 4D3p43d, 3p44d
4f3p43d 4P3p44s, 3p43d, 3p44d, 3p33d4f
5s3p44p 4Do3p44p, 3p34s5s
5p3p4p 4Po3p44p, 3p45p
5d3p44d 4F3p43d, 3p44d, 3p45d
5f3p44p 4Do3p44p, 3p44f, 3p45f
6s3p45s 4P3p44s, 3p45s, 3p46s
6p3p5 2Po3p5, 3p44p, 3p45p, 3p46p
6d3p44d(3P) 2D3p43d, 3p44d,3p45d, 3p46d
Table 2. Radial function parameters.
Table 2. Radial function parameters.
nl C jnl I jnl ξ jnl nl C jnl I jnl ξ jnl
1s0.92694117.332102p−0.0111733.10281
0.05891125.45500 0.0049732.01193
0.0078227.65768 0.1457535.19003
0.01765215.62320 0.8247826.92892
0.0009033.23731 0.08703213.04240
−0.0004732.29692
−0.0031736.726863p0.5302333.10281
0.5839132.01193
2s−0.27790117.33210 −0.0742835.19003
−0.00862125.45500 −0.2722426.92892
0.8166427.65768 −0.02506213.04240
−0.12759215.62320
0.0130633.237314p0.7440540.99510
−0.0037132.29692 0.2974040.77502
0.3312536.72686 −0.2963032.50800
0.0827627.36060
3s−0.09480117.33210
−0.00141125.455005p4.6290740.86189
0.2891427.65768 −4.6868041.00000
−0.04325215.62320 0.7352133.22166
−0.6405233.23731 −0.4035523.47369
−0.4946232.29692
0.2166536.726866p6.8280750.93715
-8.4639940.89284
4s0.4876241.29990 3.1984141.69771
0.5694741.01695 −1.1937532.71606
−0.3845732.93116 0.3085728.50855
0.1570426.14939
−0.04215114.064493d0.2497033.46562
0.8215731.68433
5s1.1332851.36491
−2.1259542.019604d0.2162532.81741
1.4872932.88430 0.3003731.89160
−0.4686825.89716 −1.1045940.96472
0.11337114.17886 0.0678240.57020
6s1.2937650.685925d0.4387532.18996
1.0843742.01936 −1.6531230.71704
−1.3501241.18083 1.9818340.61262
−0.4585932.84445
0.1207425.635726d0.5945632.11265
−0.02611114.43279 −3.2494630.71943
4.5468940.69999
4f1.0000042.15477 −2.0545840.42947
5f0.5221642.57322
−1.0446951.22476
Table 3. A-values (108 s−1) for 4p–4d transitions in Ar II.
Table 3. A-values (108 s−1) for 4p–4d transitions in Ar II.
Transition This Work
4p *4dWavelength (nm) A l A v [9][7][8]
4 P 5 / 2 o 4 F 3 / 2 319.4230.0740.0660.086 (12%) 0.236
4 P 1 / 2 o 4 F 3 / 2 326.3570.1050.0940.13 (11%)0.1550.348
4 P 5 / 2 o 4 F 7 / 2 326.8990.00310.00260.002 (84%)
4 P 5 / 2 o 4 P 5 / 2 313.9020.6250.5510.49 (18%)0.521.00
4 P 3 / 2 o 4 P 5 / 2 316.9670.5240.4550.43 (18%)0.490.817
4 P 5 / 2 o 4 P 3 / 2 318.1040.4690.4210.36 (12%)0.370.627
4 P 3 / 2 o 4 P 1 / 2 324.3691.181.051.07 (11%)1.11.99
4 P 1 / 2 o 4 P 3 / 2 324.9800.7630.6780.60 (14%)0.631.00
4 P 1 / 2 o 4 P 1 / 2 328.1700.4590.4050.41 (11%)0.420.733
4 D 3 / 2 o 4 D 1 / 2 384.1520.2580.2350.19 (12%)0.2690.267
4 D 5 / 2 o 4 D 7 / 2 384.4730.0510.0460.049 (17%)0.0480.047
4 D 5 / 2 o 4 D 5 / 2 382.6810.3250.2970.30 (15%)0.2810.345
4 D 5 / 2 o 4 D 3 / 2 379.9380.2210.1990.22 (13%)0.170.23
2 D 3 / 2 o 2 P 3 / 2 320.4320.1760.1710.24 (12%) 0.402
2 D 3 / 2 o 2 P 1 / 2 327.3320.1720.1580.20 (16%) 0.371
2 D 3 / 2 o 4 D 1 / 2 403.1380.0390.0330.07 (60%)0.075
2 D 5 / 2 o 2 D 5 / 2 295.5390.3250.2970.19 (13%)
2 D 5 / 2 o 2 D 5 / 2 301.4480.0360.0340.039 (19%)
2 P 3 / 2 o 4 F 3 / 2 383.0170.00080.00090.042 (27%)
2 P 3 / 2 o 2 F 5 / 2 365.5280.3260.3160.37 (13%) 0.232
2 P 3 / 2 o 2 P 3 / 2 329.3640.8990.8470.59 (17%) 1.73
2 P 1 / 2 o 2 P 1 / 2 330.7231.441.381.43 (11%) 3.35
2 P 3 / 2 o 2 P 1 / 2 336.6580.2710.2550.24 (15%) 0.409
2 S 1 / 2 o 2 P 3 / 2 338.8530.7610.7950.81 (12%) 1.91
2 S 1 / 2 o 2 D 3 / 2 316.1370.3700.3680.35 (45%) 1.837
4p′4d′Wavelength (nm) A l A v [9][7][8]
2 F 5 / 2 o 2 F 5 / 2 335.0920.9290.8150.90 (13%) 1.48
2 F 7 / 2 o 2 F 5 / 2 336.5520.0730.0660.075 (18%) 0.131
2 F 7 / 2 o 2 F 7 / 2 337.6440.8600.7640.74 (13%) 1.49
2 P 3 / 2 o 2 P 3 / 2 366.0440.7410.6930.73 (11%) 2.22
2 P 3 / 2 o 2 P 1 / 2 367.1010.1990.1910.23 (31%) 0.709
2 P 1 / 2 o 2 D 3 / 2 368.0060.0310.0070.59 (19%) 1.15
2 P 3 / 2 o 2 S 1 / 2 302.6750.6000.6791.03 (21%)
2 D 3 / 2 o 2 D 5 / 2 379.6590.1410.1320.18 (23%) 0.250
2 D 5 / 2 o 2 D 5 / 2 380.3170.9780.9020.89 (12%) 1.53
2 D 3 / 2 o 2 P 3 / 2 381.9020.2440.1720.15 (49%) 0.0036
2 D 5 / 2 o 2 P 3 / 2 382.5670.3840.3560.33 (55%) 0.756
* nl denotes 3p4(3P)nl; nl′ denotes 3p4(1D)nl; estimated uncertainty.

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Hibbert, A. Calculation of Rates of 4p–4d Transitions in Ar II. Atoms 2017, 5, 8. https://doi.org/10.3390/atoms5010008

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