2. Data of Meggers et al
As described in Meggers et al. [
9], those authors had only a few mg of actinium to conduct their spectral investigation. With that, they recorded about 150 photographic plates with spectrograms obtained with two different grating spectrographs, as well as a few Fabry–Perot spectrograms for analysis of hyperfine structure. Most of the spectrograms were taken with a hollow cathode light source, which produces mostly neutral-atom spectra. Several spectrograms were also taken with copper and silver spark discharges, where Ac II and especially Ac III lines were strongly enhanced. Still, the wavelength range was restricted to (2000–11,000) Å to target mostly the Ac I and Ac II spectra. The grating used in an initial study was blazed at 6000 Å, but the best spectrograms were obtained with a grating blazed at 4000 Å, so the intensities of observed lines greatly decreased towards the ultraviolet and infrared ends of the spectrum. The main source of standard wavelengths used to calibrate the spectrograms was iron, the spectrum of which was photographed on the same plates using masking of portions of the entrance slit of the spectrograph or a movable mask near the photographic plate. Auxiliary standards were also supplied by numerous impurities present in the light sources: boron, sodium, potassium, calcium, strontium, barium, magnesium, zinc, aluminum, silicon, iron, chromium, nickel, manganese, palladium, platinum, lanthanum, radium, and lead.
The wavelengths reported by Meggers et al. [
9] are “the means of 2 to 13 measurements, except a few cases where the line was classified, although observed only once”. These mean wavelengths were converted to vacuum wavenumbers. Although the air dispersion formula used was not specified, the present analysis revealed that it was the formula from Edlén 1953 [
10]. The wavelength uncertainties were not specified for each line; instead, a general statement was made: “The probable error in any wavelength is usually less than 0.01 Å; this is shown by consistent agreement of different measurements and by the close fit of classified lines.” Unfortunately, despite the high measurement precision, all wavelengths given by Meggers et al. [
9] were rounded to two digits after the decimal point. However, in the tables of classified lines of Ac III, Ac II, and Ac I (Tables 3–7 of Meggers et al., respectively), the wavelengths are accompanied by wavenumbers, which are given with a greater relative precision, especially at longer wavelengths. In the present work, the wavenumbers of these classified lines were determined as weighted averages of the wavenumber values given in the tables and those obtained from the given air wavelengths with the air dispersion formula mentioned above. Then these mean wavenumbers were converted to air wavelengths using the now-standard five-parameter formula of Peck and Reeder [
11]. Thus, the missing third digit in the wavelength was approximately restored in about half of all wavelengths.
Since detailed information about uncertainties of observed wavelengths is not available, these uncertainties have been evaluated by comparison of observed and Ritz wavelength values, as described in Ref. [
12].
Figure 1 shows a comparison of wavelengths observed by Meggers et al. [
9] with Ritz wavelengths calculated from these observed wavelengths in a least-squares level optimization procedure (see below). Only the meaningful spectral lines are shown in this figure, i.e., those for which upper and lower levels of the transition are not defined by a single observed line.
A few classified lines of Ac III are not shown in this plot, but their consistency with Ritz values is similarly good. For Ac I, the root-mean-square (rms) values of the differences
plotted in
Figure 1 are about 0.004 Å for wavelengths shorter than about 4000 Å and 0.005 Å for longer wavelengths. For Ac II, the corresponding rms values are 0.006 Å and 0.009 Å. The lines marked with characters in the intensity values (such as “h”—hazy line, “c”—complex line, etc.) showed a somewhat greater rms values, 0.006 Å for Ac I and 0.008 Å for Ac II. These estimates were adopted as measurement uncertainties for most lines. For a few lines showing greater deviations of observed wavelengths from the Ritz values, the uncertainties have been increased. For wavelengths of unclassified lines, which were all rounded to two decimal places after the point and were not accompanied by wavenumbers in the tables of Meggers et al., an uncertainty of 0.013 Å was adopted.
In addition to the first three spectra of actinium, Meggers et al. [
9] have observed six lines tentatively assigned to Ac IV (no attempts have been made to classify these lines) and several bands of the AcO molecule.
4. Ac II
For Ra-like Ac II with the ground configuration [Rn]6d7s
, Meggers et al. [
9] have listed a total of 296 observed lines, 221 of which were interpreted as transitions between the 65 energy levels found by those authors. In 1992, Blaise and Wyart [
29] published a collection of atomic data for actinide spectra, in which they included the results of unpublished theoretical work of J.-F. Wyart on Ac II. He used a parametric fitting with Cowan’s computer codes [
21] to interpret the energy structure. The [Rn](6d
+ 6d7s + 7s
+ 5f
+ 5f7p) and [Rn](5f6d + 5f7s + 6d7p + 7s7p) even- and odd-parity configuration groups were included in these calculations. In that work, Wyart rejected two levels, 5f7p
G
and 6d5f
H
, reported in Ref. [
9]. While examining the several tens of unclassified Ac II lines observed by Meggers et al. [
9], Wyart found four previously unknown levels, for which he could not find a theoretical interpretation. The principal ionization energy of Ac II was semiempirically determined by Martin et al. [
30] to be 94,800(250) cm
. For this determination, they extrapolated to Ac II the known differences of the quantum defects of the baricenters of the 7s
and 7s8s configuration in the isoelectronic Ra I spectrum (
) and of the 7s and 8s configurations in the somewhat less-similar Ra II spectrum (
). The value of
they adopted for Ac II was 1.055 ± 0.006, yielding the IE value quoted above.
The most precise theoretical calculations of the energy structure and transition properties of Ac II were made by Roberts et al. [
31]. Unfortunately, that work includes only a few of the lowest energy levels and transitions between them. It does not help much in resolving the questions remaining after the work of Wyart described above. The earlier work of Quinet et al. [
1] was made using Cowan’s suite of atomic codes [
21] modified by inclusion of a model potential describing the effects of core polarization. In a semiempirical parametric fitting with these codes, those authors included the [Rn](6d
+ 6d7s + 7s
+ 7s8s) and [Rn](5f6d + 5f7s + 6d7p + 7s7p) even- and odd-parity configuration groups, i.e., the same sets of configurations as used by Wyart, except that instead of 5f
and 5f7p, they included 7s8s in the even parity. They motivated the omission of the 5f7p configuration, which is partially known from the experiment [
9], by its strong mixing with unknown configurations, such as 7p
, 6d8s, 6d7d, and 7s7d.
The small-scale multi-configuration Dirac–Fock calculations of Ürer and Özdemir [
32] included only the 56 levels of the same eight configurations as considered by Quinet et al. [
1]. Since these calculations were ab initio, i.e., they did not include any semiempirical adjustments or core-polarization corrections, they are very inaccurate and inferior to the calculations of Ref. [
1].
To make some progress in the analysis, new parametric calculations were made in the present work with another version of Cowan’s codes [
22]. The following configuration sets were included: [Rn](6d
+ 6d7d + 6d8d + 6d9d + 6d5g + 7s
+ 7s8s + 7s9s + 7s7d + 7s8d + 7s9d + 7s5g + 6d7s + 6d8s + 6d9s + 5f
+ 5f7p + 5f8p + 5f9p + 7p
) and [Rn](7s7p + 7s8p + 7s9p + 6d7p + 6d8p + 6d9p + 5f7s + 5f8s + 5f9s + 5f6d + 5f7d + 5f8d + 5f9d + 7s6h + 6d6h + 5f5g) in the even- and odd-parity sets, respectively. The previous LSF calculations for neutral Ac made with the help of the data from the large-scale ab initio calculations of Dzuba et al. [
3] provided vital clues about the locations of the experimentally unknown configurations. Their average energies have been adjusted from the ab initio HFR values by the same amounts as configurations involving similar subshells in Ac I. As in Ac I, similar Slater parameters in all configurations were linked in groups, so that fitting of the structure of experimentally known lowest excited configurations automatically improved predictions of internal structure of the unknown highly excited configurations. The LSF calculations were conducted in the same iterative manner as in Ac I, by transferring the fitted parameters to the RCG code, calculating the transition probabilities with these fitted parameters, loading them into the input files of the IDE2 code, and searching for new levels having predicted transition wavelengths and intensities agreeing with observed lines. If one or more new levels were found, they were introduced in the LSF, and the entire procedure was repeated.
In this way, it was possible to identify 16 new energy levels describing 33 observed, previously unclassified lines. Four of these new levels are tentative, as they are based on one observed line each. One new level (at 64,154.91 cm
), based on two observed lines, is also treated as questionable, because the strongest transition predicted to occur from it at 3249.366(9) Å (down to the level at 33,388.554 cm
) is not present in the tables of Meggers et al. [
9]. Perhaps, it was mistaken for a La II line at 3249.35 Å [
8], as lanthanum is listed in Ref. [
9] as one of the many impurities. In addition, the original identification of the 5f7p
G
level [
9], which was rejected by Wyart (see above), was found to be correct and has been reinstated. For 11 levels, the previous level designation (configuration, term, or
J-value) from Blaise and Wyart [
29] has been revised. One level listed by Meggers et al. [
9] at 60,063.0 cm
and designated as
e D
has been discarded, and the two lines attributed to it in Ref. [
9] have been reclassified as transitions from other levels.
In the final LSF calculation, 45 experimentally known levels of even parity were fitted with an rms of the differences (observed minus calculated energies) of 128 cm
. For the 38 known levels of odd parity, this rms difference is 281 cm
. For the levels common with those tabulated by Roberts et al. [
31] (13 even and 3 odd), the rms difference of the present LSF calculation from the experiment is 76 cm
, to be compared with the corresponding value from Roberts et al., 456 cm
. Compared to these numbers, the results of the LSF of Quinet et al. [
1] are much worse: 1162 cm
for 18 even levels and 426 cm
for 37 odd levels. Note that, according to the present analysis, the two lowest experimental odd levels with
were interchanged in the calculations of Quinet et al. [
1], as well as in the tabulated results of Roberts et al. [
31], since their designations were interchanged in the works of Meggers et al. [
9] and Blaise and Wyart [
29]. In addition, note that, in the LSF of Quinet et al. [
1], the experimental odd-parity level at 36,144.35 cm
[
9] (
) was mistaken as 35,144.35 cm
. From the above, it is evident that the present parametric calculation is superior to all previous calculations in the accuracy of predicted energy levels.
Transition probabilities have been calculated with Cowan’s codes [
22] by using the fitted Slater parameters from the LSF. In this calculation, the values of the s–p and p–d E1 transition matrix elements were scaled by a factor of 0.9284 to bring the calculated
A-values in agreement with the calculation of Roberts et al. [
31] for the strongest transitions. This scaling factor is comparable to the one used in the Ac I calculation (0.811; see
Section 3.3). As in the Ac I calculation, the d–f and f–g E1 transition matrix elements were scaled by a factor of 0.8233 taken from the analysis of Ac III data (see
Section 5). Since the calculations of Quinet et al. [
1] and of Ürer and Özdemir [
32] were found to be too inaccurate, the only available benchmark for comparison with the present calculation is the work of Roberts et al. [
31]. Out of the total of 11
A-values tabulated by them, those of the four strongest transitions with the presently calculated line strengths
a.u. agree with the present ones within 11% on average. For the five weaker transitions with
S between 0.1 a.u. and 2 a.u., the average ratio to the present values is a factor of two, and for the two weakest transitions with
a.u., the average ratio is a factor of 9. The uncertainties of all presently calculated
A-values were roughly estimated by extrapolating this trend to all transitions considered in the present work.
All 296 observed lines attributed to Ac II by Meggers et al. [
9] are listed in
Table 4. For 270 of these lines, the table includes the lower and upper level classifications and Ritz wavelengths (one of these lines is doubly classified). For 245 of these classified lines, the table also includes a critically evaluated
A-value with its uncertainty expressed in terms of the NIST accuracy category. Most of these
A-values are from the present calculations, only four being from Roberts et al. [
31]. In addition to E1 transitions, all potentially important M1 and E2 transition probabilities have been calculated in this work. To the author’s knowledge, no data for these transitions have been previously reported. For these transitions, as in the Ac I calculations described in
Section 3.3, the method of Monte Carlo random trials [
27] was used for estimation of uncertainties of the calculated
A-values. As in Ac I, 100 random trials were used, in which the Slater parameters were randomly varied around their values from the LSF, and the variance of the E2 transition matrix elements was assumed to be 15%. In Ac II, unlike Ac I, there are two metastable or anomalously long-lived odd-parity levels with large
J-values. However, these levels have not been found experimentally, so it was not possible to include the forbidden transitions from these levels in
Table 4. Thus, all predicted forbidden transitions included in this table are between even-parity levels. These transitions have branching fractions greater than 2%. A transition is deemed to be of a mixed type (M1 + E2) if the contribution of one of the types to the total
A-value exceeds 2%.
The experimental and calculated energy levels of Ac II are listed in
Table 5. There are now 83 experimentally known Ac II levels (45 even and 38 odd). The uncertainties given for the level values in
Table 5 pertain to the separations of the levels from the 6d
F
level at 13,236.418 cm
. This level was chosen as the base for the determination of uncertainties, since it participates in the largest number of observed lines (19). The uncertainty of the excitation energy of any level from the ground level can be determined as a combination in quadrature of the uncertainty of this level given in
Table 5 and the uncertainty of the ground level, 0.03 cm
.
Table 5 also includes all levels predicted below the highest experimentally known levels in each parity (68,692.14 cm
and 56,582.72 cm
for the even and odd parity, respectively). The data from the present LSF calculations are also included in the table: energies, percentage compositions (up to three leading terms with percentages greater than 5%), Landé
-factors, and radiative lifetimes. The latter were calculated by summing up all presently considered radiative decay branches, including E1, M1, and E2 transitions. According to the present calculation, the lowest excited state 6d7s
D
at 4739.631(33) cm
is extremely long-lived. Its radiative lifetime, determined by the M1 transition to the ground state at 21,098.69(15) Å, is about 3 × 10
years (with an estimated uncertainty of 50%). This value does not account for hyperfine-induced transitions that must substantially reduce it in odd isotopes of actinium. The longest-lived isotope of actinium is
Ac with a half-life of 22 years, which sets a practical limitation on the lifetime of any excited state. The lifetime of the 6d
P
level at 19,202.962(33) cm
, which is of interest for studies of parity non-conservation [
31], is presently calculated to be 0.215(10) s. This value agrees with the result of Roberts et al. [
31], which is about 0.2 s.
Table 4.
Spectral lines of Ac II.
Table 4.
Spectral lines of Ac II.
a | a | b | c | d | Lower Level | Upper Level | e | e | Af | Acc. g | Type h | TP | Notes j |
---|
(Å) | (Å) | (Å) | (cm) | (arb.u.) | Configuration | Term | Configuration | Term | (cm) | (cm) | (s) | Ref. i |
---|
2064.280(13) | | | 48,427.6 | 14,000h | | | | | | | | | | | |
2100.000(13) | | | 47,603.9 | 27,000h | | | | | | | | | | | |
2102.240(13) | | | 47,553.2 | 3400h | | | | | | | | | | | |
2261.749(6) | 2261.7478(19) | 0.001 | 44,199.89 | 12,000 | 7s | S | 7s7p | P | 0.00 | 44,199.914 | 2.04e+08 | C+ | | TW | |
2307.500(13) | | | 43,323.62 | 9800h | | | | | | | | | | | |
2316.060(13) | | | 43,163.51 | 3500 | | | | | | | | | | | |
2344.871(6) | 2344.8721(20) | −0.001 | 42,633.21 | 4100 | 6d7s | D | 5f6d | D | 7426.489 | 50,059.68 | 8.e+06 | E | | TW | |
2501.391(6) | 2501.3942(17) | −0.003 | 39,965.71 | 2500 | 6d7s | D | 5f6d | D | 4739.631 | 44,705.290 | 8.e+06 | E | | TW | |
… | | | | | | | | | | | | | | | |
7567.652(9) | 7567.647(7) | 0.005 | 13,210.501 | 1800 | 6d | F | 6d7p | F | 13,236.418 | 26,446.928 | 5.5e+06 | C+ | | TW | |
7617.421(9) | 7617.410(7) | 0.011 | 13,124.190 | 320 | 6d | F | 6d7p | F | 16,756.847 | 29,881.055 | | | | | |
| 7626.653(12) | | | | 6d7s | D | 6d | D | 9087.517 | 22,199.428 | 3.2e+00 | D+ | M1 + E2 | TW | |
7886.822(9) | 7886.821(7) | 0.001 | 12,675.891 | 1200 | 6d | P | 6d7p | D | 19,202.962 | 31,878.854 | 1.46e+06 | C+ | | TW | |
… | | | | | | | | | | | | | | | |
| 58,385.5(4) | | | | 6d | F | 6d | F | 13,236.418 | 14,949.173 | 1.217e-01 | AA | M1 | TW | |
| 60,203.7(6) | | | | 6d7s | D | 6d7s | D | 7426.489 | 9087.517 | 1.47e-02 | C+ | M1 | TW | |
| 189,568(7) | | | | 6d7s | D | 6d7s | D | 4739.631 | 5267.147 | 3.11e-03 | A+ | M1 | TW | |
Table 5.
Energy levels of Ac II.
Table 5.
Energy levels of Ac II.
| Unc. | Configuration | Term | J | | | Leading Percentages | | | | | | Ref. | Notes |
---|
(cm) | (cm) | (cm) | | (ns) | u% |
---|
0.00 | 0.03 | 7s | S | 0 | 95 | | | | | | | 0 | 0.000 | | | TW,M,BW | |
4739.631 | 0.018 | 6d7s | D | 1 | 99 | | | | | | | 4661 | 0.499 | 1.0e+23 | 52 | TW,M,BW | |
5267.147 | 0.015 | 6d7s | D | 2 | 86 | 11 | 6d7s | D | | | | 5281 | 1.145 | 1.58e+11 | 19 | TW,M,BW | |
7426.489 | 0.016 | 6d7s | D | 3 | 99 | | | | | | | 7498 | 1.334 | 6.32e+09 | 1.7 | TW,M,BW | |
9087.517 | 0.014 | 6d7s | D | 2 | 68 | 16 | 6d | D | 13 | 6d7s | D | 9087 | 1.015 | 1.61e+09 | 18 | TW,M,BW | |
13,236.418 | 0.000 | 6d | F | 2 | 93 | | | | | | | 13,191 | 0.687 | 1.96e+09 | 22 | TW,M,BW | |
… | | | | | | | | | | | | | | | | | |
28,201.120 | 0.021 | 7s7p | P | 2 | 89 | 7 | 6d7p | P | | | | 28,324 | 1.480 | 25.2 | 9 | TW,M,BW | C |
| | 6d | S | 0 | 83 | 6 | 6d | P | | | | 29,025 | 0.000 | 4.e+04 | 760 | | |
… | | | | | | | | | | | | | | | | | |
64,154.91 | 0.08 | 6d7d | D | 2 | 28 | 15 | 7p | D | 13 | 7p | P | 64,487 | 1.121 | 2.21 | 7 | TW | T |
64,285.02 | 0.05 | 6d7d | F | 4 | 72 | 18 | 6d7d | G | 6 | 6d7d | G | 64,218 | 1.194 | 3.07 | 5 | TW,BW | C,J |
64,332.11 | 0.06 | 5f7p | D | 3 | 47 | 17 | 6d7d | D | 17 | 5f7p | F | 64,316 | 1.225 | 3.01 | 5 | TW | N |
| | 5f7p | D | 2 | 13 | 27 | 6d7d | D | | | | 64,660 | 1.146 | 2.32 | 6 | | |
| | 6d7d | P | 1 | 64 | 29 | 6d7d | S | | | | 65,242 | 1.635 | 2.2 | 12 | | |
65,392.37 | 0.04 | 5f7p | G | 5 | 52 | 48 | 6d7d | G | | | | 65,385 | 1.200 | 2.82 | 8 | TW | RI |
| | 6d7d | G | 4 | 66 | 11 | 6d7d | F | | | | 65,799 | 1.040 | 4.2 | 7 | | |
| | 6d7d | P | 2 | 47 | 24 | 5f7p | D | | | | 65,894 | 1.284 | 2.64 | 8 | | |
| | 6d7d | S | 0 | 62 | 15 | 6d7d | P | | | | 66,901 | 0.000 | 5.2 | 25 | | |
68,692.14 | 0.06 | 7p | D | 2 | 34 | 14 | 5f7p | D | 12 | 7p | P | 68,668 | 1.089 | 1.40 | 6 | TW | N |
[94,800] | 250 | Ac III (6p7s S) | Limit | | | | | | | | | | | | | M74 | |
The presently calculated Landé factors included in
Table 5 agree with those previously calculated by Quinet et al. [
1], with rms differences of 0.017 in the even parity and 0.06 in the odd parity. In the absence of a better benchmark for comparison, these rms differences can be adopted as the uncertainties of the present values.
No attempt was made here to re-evaluate the IE of Ac II. Thus, the recommended value of IE included in
Table 5 is the semiempirical one quoted from Martin et al. [
30].
The final fitted values of the Slater parameters resulting from the present LSF for Ac II are listed in
Table 6.
Table 6.
Parameters of the least-squares fit for Ac II.
Table 6.
Parameters of the least-squares fit for Ac II.
Parity | Configurations | Parameter | LSF a (cm) | b (cm) | Gr. c | HFR a | Ratio a |
---|
e | 7s | | | | 171 | | | |
e | 7s8s | | | | 132 | 3 | | 1.0854 |
e | 7s8s | | (7s,8s) | | 127 | 9 | | 0.4666 |
e | 7s9s | | | | 178 | 3 | | 1.0626 |
e | 7s9s | | (7s,9s) | | 42 | 9 | | 0.4667 |
e | 7s7d | | | | 262 | 6 | | 1.0880 |
e | 7s7d | | | | 8 | 10 | | 0.8362 |
e | 7s7d | | (7s,7d) | | 77 | 1 | | 0.6848 |
e | 7s8d | | | | 330 | 6 | | 1.0713 |
e | 7s8d | | | | 3 | 10 | | 0.8359 |
e | 7s8d | | (7s,8d) | | 29 | 1 | | 0.6848 |
… | | | | | | | | |
e | 7s7d | 6d8s | (7s7d,6d8s) | | 164 | 15 | | 0.5669 |
e | 7s7d | 6d8s | (7s7d,6d8s) | | 70 | 15 | | 0.5669 |
e | 7s7d | 5f7p | (7s7d,5f7p) | | 58 | 15 | | 0.5669 |
e | 7s7d | 5f7p | (7s7d,5f7p) | | 55 | 15 | | 0.5669 |
e | 6d7d | 5f7p | (6d7d,5f7p) | | 181 | 15 | | 0.5669 |
e | 6d7d | 5f7p | (6d7d,5f7p) | | 51 | 15 | | 0.5669 |
e | 6d7d | 5f7p | (6d7d,5f7p) | | 23 | 15 | | 0.5669 |
e | 6d7d | 5f7p | (6d7d,5f7p) | | 1 | 15 | | 0.5672 |
e | 6d7d | 7p | (6d7d,7p7p) | | 159 | 15 | | 0.5669 |
e | 6d7d | 7p | (6d7d,7p7p) | | 76 | 15 | | 0.5669 |
e | 5f7p | 7p | (5f7p,7p7p) | | 209 | 15 | | 0.5669 |
o | 7s7p | | | | 195 | | | 1.2336 |
o | 7s7p | | | | 172 | 5 | | 1.3553 |
o | 7s7p | | (7s,7p) | | 1104 | 4 | | 0.6083 |
o | 7s8p | | | | fixed | | | 1.0937 |
o | 7s8p | | | | 55 | 5 | | 1.3553 |
o | 7s8p | | (7s,8p) | | 155 | 4 | | 0.6083 |
… | | | | | | | | |
o | 6d7p | 5f7s | (6d7p,5f7s) | | 517 | 9 | | 0.5690 |
o | 6d7p | 5f7s | (6d7p,5f7s) | | 703 | 7 | | 0.6614 |
o | 6d7p | 5f8s | (6d7p,5f8s) | | 26 | 9 | | 0.5690 |
o | 6d7p | 5f8s | (6d7p,5f8s) | | 157 | 7 | | 0.6614 |
o | 6d7p | 5f9s | (6d7p,5f9s) | | 9 | 9 | | 0.5689 |
o | 6d7p | 5f9s | (6d7p,5f9s) | | 78 | 7 | | 0.6614 |
o | 6d7p | 5f6d | (6d7p,5f6d) | | 378 | 9 | | 0.5690 |
o | 6d7p | 5f6d | (6d7p,5f6d) | | 201 | 9 | | 0.5690 |
… | | | | | | | | |
5. Ac III
The ground state of francium-like Ac III is [Rn]7s. Meggers et al. [
9] have identified eight lines of Ac III, from which they determined the values of six excited levels. All these identifications have been confirmed here. The wavelengths reported by Meggers et al. [
9] are internally consistent: they deviate from the Ritz values by less than 0.003 Å. However, the strong polar effect in the setup of Meggers et al. [
9] may have led to a sizeable systematic shift in the measured wavelengths. Thus, the uncertainties of these measurements are conservatively estimated to be 0.013 Å for the lines above 3000 Å. For lines with shorter wavelengths, which are likely to have been measured in both the first and second orders of diffraction, a smaller uncertainty of 0.006 Å is assumed here. The list of observed lines of Ac III is given in
Table 7.
As for Ac I and Ac II, the experimental energy levels have been redetermined here from the eight observed spectral lines by means of a least-squares level optimization with the code LOPT [
28]. The list of the newly optimized energy levels of Ac III is given in
Table 6. Separations of the optimized excited levels from the 6d
D
level at 4203.89 cm
have uncertainties in the range from 0.04 cm
to 0.10 cm
. These uncertainties are given in
Table 6. To obtain the uncertainties of excitation energies from the ground level (7s
S
), they must be combined in quadrature with the uncertainty of the ground level, 0.09 cm
.
On the theoretical side, the most precise reported calculations of energy levels and E1 transition rates are those of Roberts et al. [
33], of Safronova et al. [
34], and of Migdalek and Glowacz-Proszkiewicz [
35]. For Ac III, E1 transition rates of Roberts et al. [
33] and Safronova et al. [
34] agree with each other within 3% on average. For only two longest-wavelength transitions (6d
D
–5f
F
), the difference between these two calculations reaches 5%. The
A values of Roberts et al. [
33] have been adopted here as recommended values. Their uncertainties are assigned according to the comparison outlined above. The
A values of Migdalek and Glowacz-Proszkiewicz [
35] deviate from those of Roberts et al. [
33] by 5% on average. For the
A values of Biémont et al. [
36], the average deviations from Ref. [
33] are slightly larger; 9% on average. For comparison, the
A values computed by Ürer and Özdemir [
37] are systematically lower than the reference values by (53 ± 30)% on average. These primitive Dirac–Fock calculations included only six configurations of even parity and five configurations of odd parity. The poor quality of the results speaks for itself.
Although Cowan-code calculations cannot compete in accuracy with the large-scale calculations of Roberts et al. [
33] and Safronova et al. [
34], such calculations were made in this work with the sole purpose of evaluation of systematic errors in the transition matrix elements computed with Cowan’s codes. The scaling factors needed to bring the calculated E1
A values were 0.9510 for the s–p and p–d transitions and 0.8233 for the d–f and f–g transitions. The latter factor was used in the Ac I and Ac II calculations, where no reference values are available for an independent estimation.
Parity-forbidden E2 and M1 transition rates for transitions from the lowest two excited levels of Ac III have been reported by Safronova et al. [
38]. These authors have included their estimated uncertainties for the
A values and radiative lifetimes. These uncertainties are between 0.4% and 1.5%. The reference values taken from Ref. [
38] have been used here to evaluate the systematic errors in the E2 transition matrix elements computed with Cowan’s codes. It turned out that, unlike the E1 transitions, the E2
A values computed with Cowan’s code agree with the reference values within a few percent with no discernible systematic difference. This observation in Ac III was extrapolated to the other Ac spectra, so that no scaling was applied to the E2 transition matrix elements in any of the spectra studied in this work.
The Landé
factors of the three lowest levels of Ac III were precisely calculated by Gossel et al. [
39]. The rms difference of the
values calculated in that work from much more precise experimental values for Rb, Cs, Ba
, and Fr is
, which can be adopted as an estimate of uncertainty for the Ac III values.
The currently recommended values of the principal ionization energy (IE) of Ac III, 140,590 cm
[
8], is quoted from Migdalek and Glowacz-Proszkiewicz [
35]. Its estimated uncertainty, 160 cm
, was derived from isoelectronic comparisons made in my unpublished research on the Fr isoelectronic sequence made in 2011. The newer calculations of Roberts et al. [
33], as well as the calculations of Safronova et al. [
34], which were overlooked in my early research, make it possible to establish a more precise value of the IE. A fairly extensive study of these data was undertaken in the present work. Unfortunately, the data of Migdalek and Glowacz-Proszkiewicz [
35], as well as those of Safronova et al. [
34], were found to contain errors that make them not smooth along the isoelectronic sequence.
The coefficient
b given below Equation (5) of Migdalek and Glowacz-Proszkiewicz [
35] has a misprint in the power of 10: it must be
, not
. However, even with the corrected
b value, the values of the dipole polarizability
in
Table 1 of that paper cannot be reproduced with the given equation. There is a discontinuity in the
values between Ac and Th, which is revealed in the residual differences between the
values of Table 1 of Ref. [
35] and those computed with Equation (5) of that paper. The cause of this discontinuity may be in the values of the mean radii given in the same table, which are supposed to be fitted for Fr I through Th IV and extrapolated to the higher ions.
In the paper of Safronova et al. [
34], there are several inconsistencies between their Table I and Table II. For example, for Fr I, the excitation energies of 6d
and 6d
given in Table II disagree with Table I by 286 cm
and 208 cm
, respectively. For the U VI 7p
and 7p
levels, the disagreement is much larger: 519 cm
and 1450 cm
, respectively. Table I of Ref. [
34] lists the values of several computed quantities representing various contributions to the total binding energy. Some of these contributions are relatively small and are expected to vary smoothly along the isoelectronic sequence. However, this smoothness is disrupted by the abnormally large values of the parameters
and
for the 7p
level of Pa V. An isoelectronic comparison of the binding energies of the 6d
and 6d
levels computed with two methods by Safronova et al. [
34] with those of Roberts et al. [
33] reveals that the latter are likely to be too high by about 1000 cm
in Pa V.
Despite the problems discussed above, it was possible to interpolate the differences between the experimental and theoretical values of quantum defects for the 7s
, 6d
, 7p
, and 5f
levels along the Fr isoelectronic sequence from Fr I to U VI and derive improved values of the IE for Ac III, Th IV, Pa V, and U VI. These values are 140,630(50) cm
, 230,973(14)) cm
, 361,690(200) cm
, and 506,400(50) cm
, equivalent to 17.436(6) eV, 28.6371(17) eV, 44.844(25) eV, and 62.786(6) eV, respectively. A detailed description of these isoelectronic interpolations will be the subject of a future paper. The above IE value for Th IV has been derived from a newly reoptimized set of experimental energy levels based on the wavelengths reported by Klinkenberg [
40]. The series of the
ns
(
–10) energy levels was used in this determination, which employed a fitting of the extended Ritz quantum-defect expansion formula (see Kramida [
12]) and comparisons with similar series in isoelectronic Fr I and Ra I.
A more precise determination of the IE could be made in the future, when more accurate calculations become available. Such calculations are desirable for the entire sequence from Fr I up to Np VII (for the latter spectrum, the only data available at present are those of Roberts et al. [
33]). These calculations should be smooth along the isoelectronic sequence and include not only the levels listed above, but also 7d (
), 8p (
), and 8s (
). These levels are precisely known experimentally for Fr I and Ra II, but in U VI their experimental values are provided with a rather low precision by the beam-foil study of Church et al. [
41]. The abnormally large deviations of quantum defects of the 8p levels from the calculations of Roberts et al. [
33] make the identifications of Church et al. [
41] questionable. In terms of excitation energy, the discrepancy is about 4600(1600) cm
for the 8p
level. More precise calculations could confirm or disprove this experimental identification.
The lists of observed spectral lines and energy levels of Ac III are given in
Table 7 and
Table 8, respectively. Data for predicted forbidden transitions of Ac III are included in
Table 7 for completeness. The lifetime values included in
Table 8 are computed as sums of the E1, M1, and E2 radiative decay channels. The lifetime value for the 6d
D
level, 2.305(34) s, differs slightly from the value originally reported by Safronova et al. [
38], 2.326(34) s, possibly because in the present work the
A values have been adjusted to experimental transition energies. The original values of the reduced transition matrix elements reported in Ref. [
38] have been used here.
Table 7.
Spectral lines of Ac III.
Table 7.
Spectral lines of Ac III.
| | | | | Lower Level | Upper Level | | | A | Acc. | Type | TP |
---|
(Å) | (Å) | (Å) | (cm) | (arb.u.) | Configuration | Term | Configuration | Term | (cm) | (cm) | (s) | Ref. |
---|
2626.440(6) | 2626.439(5) | 0.001 | 38,063.00 | 300,000 h | 7s | S | 7p | P | 0.00 | 38,063.01 | 3.97e+08 | A | | R13,S07 |
2682.900(6) | 2682.899(4) | 0.001 | 37,262.03 | 23,000 h | 6d | D | 7p | P | 800.97 | 38,063.01 | 2.89e+07 | A | | R13,S07 |
2952.550(6) | 2952.551(5) | −0.001 | 33,859.13 | 230,000 h | 6d | D | 7p | P | 4203.89 | 38,063.01 | 2.30e+08 | A | | R13,S07 |
3392.780(13) | 3392.782(10) | −0.002 | 29,465.90 | 78,000 Dh | 7s | S | 7p | P | 0.00 | 29,465.88 | 1.90e+08 | A | | R13,S07 |
3487.590(13) | 3487.588(11) | 0.002 | 28,664.89 | 99,000 | 6d | D | 7p | P | 800.97 | 29,465.88 | 1.58e+08 | A | | R13,S07 |
4413.090(13) | 4413.093(11) | −0.003 | 22,653.50 | 34,000 h | 6d | D | 5f | F | 800.97 | 23,454.45 | 1.85e+07 | A | | R13,S07 |
4569.870(13) | 4569.870(13) | | 21,876.33 | 65,000 h | 6d | D | 5f | F | 4203.89 | 26,080.22 | 2.11e+07 | B+ | | R13,S07 |
5193.211(13) | 5193.208(12) | 0.003 | 19,250.55 | 710 h | 6d | D | 5f | F | 4203.89 | 23,454.45 | 8.79e+05 | B+ | | R13,S07 |
| 23,787.5(5) | | | | 7s | S | 6d | D | 0.00 | 4203.89 | 3.748e-03 | AA | E2 | S17 |
| 29,386.5(6) | | | | 6d | D | 6d | D | 800.97 | 4203.89 | 4.30e-01 | A+ | M1 | S17 |
| 124,849(14) | | | | 7s | S | 6d | D | 0.00 | 800.97 | 8.48e-07 | AA | E2 | S17 |
Table 8.
Energy levels of Ac III.
Table 8.
Energy levels of Ac III.
| Unc. | Configuration | Term | J | Perc. | | (cm) | |
---|
(cm) | (cm) | TW | [39] | [35] | [33] | [34] | (ns) |
---|
0.00 | 0.09 | 7s | S | 1/2 | 99 | 2.002 | 2.005606 | 0 | 0 | 0 | |
800.97 | 0.06 | 6d | D | 3/2 | 99 | 0.800 | 0.798662 | 562 | 435 | 825 | 1.171(6)e15 |
4203.89 | 0.00 | 6d | D | 5/2 | 99 | 1.200 | 1.200627 | 4040 | 3926 | 4041 | 2.305(34)e9 |
23,454.45 | 0.04 | 5f | F | 5/2 | 100 | 0.857 | | 29,906 | 23,467 | 24,018 | 52(3) |
26,080.22 | 0.06 | 5f | F | 7/2 | 100 | 1.143 | | 32,063 | 26,112 | 26,420 | 48(3) |
29,465.88 | 0.10 | 7p | P | 1/2 | 100 | 0.666 | | 29,382 | 29,375 | 29,303 | 2.88(14) |
38,063.01 | 0.06 | 7p | P | 3/2 | 100 | 1.334 | | 37,987 | 38,136 | 37,816 | 1.53(8) |
[140,630] | 50 | Ac IV (6p S) | Limit | | | | | 140,590 | 141,221 | 140,442 | |
6. Reduction of Observed Line Intensities
Meggers et al. [
9] have reported five sets of observed line intensities from the five types of light sources they used: an arc and a spark between silver electrodes, an arc and a spark between copper electrodes, and a hollow-cathode discharge. These light sources are denoted hereafter as “Ag arc”, “Ag spark”, “Cu arc”, “Cu spark”, and ”HC”, respectively. Small amounts of actinium were introduced into these light sources by soaking porous tips of the electrodes in a nitrate solution of Ac or by precipitating a similar solution on the bottom of the hollow cathode. No information was given by Meggers et al. [
9] about the methods used in reduction of the observed intensities. They mentioned that several different types of photographic plates were used in different recordings: Eastman Kodak 103-F, 103-C, 103a-C, 103a-F, 103a-F (UV), I-N, and I-Q. For the most informative recordings, the 103a-F (UV) plates were used for the ultraviolet region, 103a-F for near ultraviolet and visible, I-N for red and adjacent infrared, and I-Q for longer wavelengths. It was noted that, in some exposures, “overlapping spectral orders were differentiated by supporting appropriate gelatine filters in front of the photographic plates to absorb portions of the slit images”. The intensity values were given in the tables of Meggers et al. [
9] on an apparently linear scale (in terms of exposure) with values between 1 and 5000. However, no information about the dependence of the overall sensitivity of the multiple setups on wavelength is available. The different light sources had notably different temperatures, which was manifested in enhanced intensities of Ac II and Ac III lines in sparks. Thus, reduction of all these intensity measurements to a common scale is a nontrivial task.
To achieve that, the present work uses the method suggested by Kramida [
12] and described in more detail in later publications (see, e.g., Kramida et al. [
42,
43]). This method is based on the assumption of the Boltzmann distribution for the populations of excited levels and neglects self-absorption. The important prerequisite for this method to work is the availability of reliable
A values for most of the lines throughout the entire spectral range of the observations. These requirements are likely to have have been met: extensive sets of fairly accurate
A values are available for all three spectra (Ac I, Ac II, and Ac III; see
Table 1,
Table 5 and
Table 7), the tiny amounts of Ac introduced into the discharges make self-absorption to be unlikely, and the level populations in all types of the light sources used by Meggers et al. [
9] are sufficiently close to local thermodynamic equilibrium.
The effective excitation temperatures determined from the slopes of Boltzmann plots (see [
12,
42,
43]) in the various light sources used by Meggers et al. [
9] are listed in
Table 9 for each Ac spectrum. From the scatter of data points in the plots, uncertainties of these values are can be roughly estimated as about 20%.
As can be seen from
Table 9, the observed spectra of different ions exhibit different excitation temperatures in the same light source. This is due to the different spatial origin of the spectra, which can be seen in Figures 2 and 3 of Meggers et al. [
9]: lines of Ac I, Ac II, and Ac III have distinctly different distributions of intensities along the line height. For Ac III spectra taken with the Cu arc and HC discharges, it was not possible to determine the temperature, because only a few transitions with relatively close upper-level energies were observed in these spectra. For these spectra, the slope of the Boltzmann plots was fixed at zero in the intensity-reduction procedure.
The logarithmic inverse spectral response plots (see [
12,
42,
43]) derived from the observed intensities are displayed in
Figure 6. The inverse spectral response function
is defined as
, where
is the observed wavelength,
is the calculated intensity, and
is the observed intensity. To remove the wavelength-dependence of the spectral response of the instrument from the observed intensities, the latter are multiplied by exp(
).
It was found that Meggers et al. [
9] used different intensity-reduction procedures in the short-wavelength (
Å) and long-wavelength (
Å) regions. However, in each of these regions, the same reduction procedure was applied to certain groups of spectra. This can be seen, for example, in the top-left panel of
Figure 6, showing the behavior of the observed Ac I intensities. There is no discernible difference in the shape of
between the Ag arc, Ag spark, Cu arc, and Cu spark spectra, so they are all displayed with the same symbol (full rhombus). The ratios
for the HC intensities may be perceived from the plot as slightly deviating from the overall fit shown by the dotted line, but these deviations are within the range of scatter of the data points. Thus, a common
function shown by the dotted curve was used to correct the observed intensities in all these spectra.
A similar comparison is shown in the same wavelength range for the Ac II and Ac III spectra in the bottom-left panel of
Figure 6. Again, the general behavior of the
values is very similar for both Ac II and Ac III spectra recorded with Ag and Cu arcs and sparks and with HC. However, this behavior is very different from the one observed for the Ac I spectrum: at the shortest wavelengths below 3500 Å, the observed Ac II and Ac III intensities appear to be strongly suppressed, so that larger
values are needed to bring them in agreement with the calculated intensities. This suppression may have been caused by the use of filters to suppress higher orders of diffraction. Again, a common
function shown by the dotted curve was used to correct the observed intensities in all spectra included in this panel.
For the long-wavelength region above 5000 Å, a different division is observed between the various spectra. As shown in the top-right panel of
Figure 6, all three actinium spectra appear to have the same scale of intensities observed in the arc and spark recordings. The overall shape of the
function shown by the dotted curve, with a minimum near 6000 Å, is very reasonable, since the grating used in these recordings was blazed at this wavelength. However, the HC recordings (bottom-right panel of
Figure 6) display a very different behavior of
at the longest wavelengths above 6500 Å. Near 8000 AA, the observed HC relative intensities are much greater (by about two orders of magnitude) compared to the arc and spark intensities. The exact cause of the increased HC intensities at longer wavelengths is unknown. It might have been caused by the use of a different type of photographic plates in these recordings.
When the shapes of the
function are established for each observed spectrum, and the effective temperatures are determined from Boltzmann plots, reduction of the observed intensities to a common scale corresponding to a chosen light source is straightforward (see a detailed description of this procedure in Kramida et al. [
43]). For Ac I, the observed intensities given in
Table 1 have been reduced to the same scale as established for the Ag arc recordings with an effective temperature of 0.51 eV. For Ac II and Ac III intensities given in
Table 4 and
Table 7, respectively, the scale was based on the Ag spark observations with effective temperatures of 0.77 eV and 2.18 eV for Ac II and Ac III, respectively (see
Table 9). Most of the tabulated intensity values are averages of several reduced intensity values from up to five observations in different light sources. These intensity values are expected to be accurate within a factor of two or three, on average. In principle, they allow the
values to be derived from them (with that low accuracy) by constructing a Boltzmann plot with the temperatures given above (see Equation (
1)). The scatter of the data points in
Figure 6 suggests that a few of the intensity values may be in error by a factor of 10, or even more.