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.
Energy level separations in high-lying Rydberg states of neutral aluminium have
been measured by a two-photon millimetre-wave resonance method to obtain
n 2F–(n + 1) 2F intervals for
n = 29–37 with
an accuracy ±1
MHz. An Al atomic beam was excited stepwise by pulsed lasers, and the
Rydberg atoms were detected by state-selective field ionization. From
these data and previous optical data for the 3s2nℓ
configuration of Al I new Ritz-expansion coefficients, which express the weakly
n-dependent quantum defects
for the nF
Rydberg series, have been obtained. A previous laser-spectroscopic study of 2F
Rydberg levels in Al I is shown to be in error, and quantum defects based on the
classical spectroscopic work of Eriksson and Isberg are confirmed. The nF
series is completely regular and shows no sign of perturbations by other electronic
configurations.
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