Study of the ns<sup>2</sup>S and nd<sup>2</sup>D Rydberg series in aluminium

Buurman, E. P.; Koning, O.J.; Dönszelmann, A.

doi:10.1088/0953-4075/22/24/004

Cited by 9 publications

(12 citation statements)

References 10 publications

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“…Al(3s 2 nd)n 2 D states have been investigated by optical spectroscopy [1][2][3][4], but the results give values of the quantum defects of unknown accuracy whose values are unconfirmed. In these the doublet fine structure is at best only partially resolved [4].…”

Section: Introductionmentioning

confidence: 99%

Microwave spectroscopy of Al I atoms in Rydberg states: D and G terms

Dyubko

Ефремов

Gerasimov

et al. 2003

J. Phys. B: At. Mol. Opt. Phys.

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We present results of microwave and millimetre-wave resonance measurements in D, F and G Rydberg states of neutral aluminium in the frequency range 4-423 GHz for principal quantum numbers n = 22-43. In all, 12, 27 and 19 resonances of nF2 D 5/2 and nF → nG or nF → (n + 1)G series, respectively, have been recorded. D-state fine-structure doublet splittings have been obtained with accuracy ±1.4 MHz. For D and G states, quantum defect Ritz-expansion parameters have been determined, from which the Rydberg series can be accurately reconstructed to an accuracy of order ±1 MHz (3 × 10 −5 cm −1 ) for all n.

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Section: Introductionmentioning

confidence: 99%

Microwave spectroscopy of Al I atoms in Rydberg states: D and G terms

Dyubko

Ефремов

Gerasimov

et al. 2003

J. Phys. B: At. Mol. Opt. Phys.

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“…As a results we have obtained the sets of constants for calculation of quantum defect in S, P, D, and F states that fit best of all both microwave absorption spectra and optical spectra published by the authors of the works [1][2][3][4][5]. These sets of constants are presented in Table 1.…”

mentioning

confidence: 83%

“…The last method is accepted as providing the highest accuracy of 1 cm -1 and higher. The authors of works [1][2][3][4][5] used this method to determine the ionization potential of Al atoms. We propose a method of specification of the ionization potential that based on the joining of the most accurate direct measurements of transition frequencies from the ground state to the excited states of the atom in optic wavelength range T nlj with highprecision calculations of atomic energy E(n,l,j) in Rydberg states.…”

mentioning

confidence: 99%

“…The values T nlj can be taken from mentioned above works [1][2][3][4][5]. The E(n,l,j) component is the energy levels of Al corresponding to quantum number n, l, j may be parameterized by the Rydberg formula …”

mentioning

confidence: 99%

“…If such "joining" of mentioned energies is fulfilled in the range with n > 4 the accuracy of V IP will be determined first of all by the accuracy of optic measurements. The values of ionization potential that were obtained earlier by the authors [1][2][3][4][5] are presented in Table 2. Our result is given in this table in the last row.…”

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confidence: 99%

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Specification of the Ionization Potential of AlI

Ефремов

Dyubko

Gerasimov

et al. 2006

2006 International Workshop on Laser and Fiber-Optical Networks Modeling

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A joint analysis of high-precision microwave measurements of transition frequencies of Al atoms in S, P, D, and F Rydberg states obtained by the authors and spectroscopic data from optic wavelength range allowed us to determine a new value for ionization potential of Al atoms V IP = 48278,53±0,02 cm -1 .Ionization potentials V IP of atoms and molecules are fundamental quantities of great importance in many areas of physics and chemistry. They provide crucial information on the electronic structure and, therefore, are often used as benchmarks for theoretical methods. Also when used in the appropriate thermodynamic cycles, V IP relate to bond strengths. The accuracy of calculation of ionization potentials of multi electron atoms for the time being is not satisfactory and that is why they are determined using experimental methods: method of surface ionization, method of electron impact, method of spectral extrapolation, method of two and three stage ionization, and method of fitting Rydberg series. The last method is accepted as providing the highest accuracy of 1 cm -1 and higher. The authors of works [1][2][3][4][5] used this method to determine the ionization potential of Al atoms. We propose a method of specification of the ionization potential that based on the joining of the most accurate direct measurements of transition frequencies from the ground state to the excited states of the atom in optic wavelength range T nlj with highprecision calculations of atomic energy E(n,l,j) in Rydberg states. We used this method earlier for specification of ionization potential of Au I [6]. In the present paper we apply this method to the specification of ionization potential V IP of aluminum. Therefore we have:

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Fine structure in the 3s3p²²D perturber of the 3s²nd²D series in aluminium

Burrman¹,

Davidson²,

Uylings³

et al. 1990

J. Phys. B: At. Mol. Opt. Phys.

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We investigated the 3s'ns 'S, 3s'nd 'D and the 3s2nf 'F series in aluminium. These high levels were populated by three-photon two-step excitations using the 3s24p 2P3,2 as the intermediate state. We determined the positions of the series members accurately for n values between 28 and 60. The 'S and the *F series are not perturbed. The quantum defect of the ' S series is confirmed to be 1.728 (2), the quantum defect of the 2F series is 0.041 (2). The perturbation of the 2 D series is demonstrated by the variation of the quantum defect over the series, and by the fine structure (FS) of the *D levels which is measured for n < 37. The large positive splitting is shown to be explained by taking into account the fine structure ofthe 3s3p2 'D perturber. Using simple arguments the percentage of admixture of 3s3p2'D to the 3s'nd'D series can be determined while the FS of the perturber is estimated to be 20.5 cm-'.

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Study of the ns²S and nd²D Rydberg series in aluminium

Cited by 9 publications

References 10 publications

Microwave spectroscopy of Al I atoms in Rydberg states: D and G terms

Microwave spectroscopy of Al I atoms in Rydberg states: D and G terms

Specification of the Ionization Potential of AlI

Fine structure in the 3s3p²²D perturber of the 3s²nd²D series in aluminium

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Study of the ns2S and nd2D Rydberg series in aluminium

Cited by 9 publications

References 10 publications

Microwave spectroscopy of Al I atoms in Rydberg states: D and G terms

Microwave spectroscopy of Al I atoms in Rydberg states: D and G terms

Specification of the Ionization Potential of AlI

Fine structure in the 3s3p22D perturber of the 3s2nd2D series in aluminium

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Study of the ns²S and nd²D Rydberg series in aluminium

Fine structure in the 3s3p²²D perturber of the 3s²nd²D series in aluminium