Core effect on the diamagnetic spectrum of barium Rydberg states

Yang, Haifeng; Gao, Wei; Quan, Wei; Liu, X. J.; Liu, H. P.

doi:10.1103/physreva.85.032508

Cited by 15 publications

(25 citation statements)

References 41 publications

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“…The experiment is performed on the same apparatus described previously, [21,22] here we just summarize the main features and improvements. A sodium atomic beam spouted from a resistance-heated oven travels to the interaction region after being collimated by two pin-holes with diameters of about 2 mm.…”

Section: Methodsmentioning

confidence: 99%

“…The calculation has been introduced in detail in our previous works, [20,21,24] here we only summarize the main steps. In the presence of external parallel electric and magnetic fields oriented along the z-axis, in atomic units by the convention, the non-relativistic Hamiltonian H for the Rydberg sodium atom can be written as follows: [20]…”

Section: Theoretical Calculationmentioning

confidence: 99%

“…All the spectra are calculated with our newly developed quantum method combining the quantum defect orbit model and the B-Spline basis. [20,21]…”

Section: Introductionmentioning

confidence: 99%

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Non-linear spectral splitting of Rydberg sodium in external fields

Gao¹,

Yang²,

Cai³

et al. 2015

Chinese Phys. B

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We have studied highly excited sodium in various electric fields, parallel electric and magnetic fields, with one σ and π photon irradiation, and even in a magnetic field with a complex laser polarization configuration. The σ spectra shows a simple linear Stark effect with the applied electric field, while the π spectra exhibits a strong non-linear dependence on the electric field. The π transitions in parallel fields show a similar behavior to that in a pure electric field but the spectra get more smooth due to the magnetic field. The diamagnetic spectrum with laser polarization angles between 0 and π/2 proves that it can be reproduced by simple linear combination of π and σ components, indicating there is no interference between the π and σ channels. A full quantum calculation considering the quantum defects accounts for all the observations. The quantum defects, especially for the channel np, play an important role in the spectral profile.

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Section: Methodsmentioning

confidence: 99%

Section: Theoretical Calculationmentioning

confidence: 99%

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Non-linear spectral splitting of Rydberg sodium in external fields

Gao¹,

Yang²,

Cai³

et al. 2015

Chinese Phys. B

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“…[5,6] For an atom in a strong magnetic field, the diamagnetic term in the Hamiltonian makes the system non-separable even for a hydrogen atom. [2] Researchers have developed a semiclassical method [7,8] and quantum calculation [9,10] to treat this problem and explain the correlative experiments. [11,12] Although there is a quadratic term in the Hamiltonian, the atom in a magnetic field has a simpler structure [13,14] than the Stark spectrum [6,15] for its higher symmetry.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear spectroscopy of barium in parallel electric and magnetic fields

et al. 2014

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We report on the experimental spectral observations of barium in parallel electric and magnetic fields. The laser pulse is linearly polarized along or perpendicular to the fields, leading to the states m = 0 and the states m = ±1 populated, respectively, by one photon excitation. By sweeping the electric field, we observe the linear and nonlinear splitting of the diamagnetic spectrum as the electric field increases. The spectral anticrossing is induced by the atomic core effect. The Stark spectrum also shows an obvious nonlinear quadratic behavior when the applied magnetic field varies strongly. All spectra are well explained by the full quantum calculation after taking the quantum defect effects of the channel ns up to nf into account.

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“…The numerical calculation is carried out based on the well-developed full quantum method. [9,10] The energy range examined in this study is from −47 cm −1 to −39 cm −1 and the magnetic field strength is 0.57 T, where the spectrum is on the edge of inter-𝑛 mixing. The electric field is swept from 0 to 23 V/cm, with the spectrum evolving from inter-𝑙 mixing to deep inter-𝑛 mixing.…”

mentioning

confidence: 99%

Electron Dynamics of Atoms in Parallel Electric and Magnetic Fields

Yang

Gao

Cai

et al. 2014

Chinese Phys. Lett.

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Through an analysis of the nearest neighbor level spacing statistics for atoms in parallel electric and magnetic fields, we investigate the evolution of the electron dynamics as electric field strength increases. In the 'inter-𝑙 mixing' predominant region, the electron shows complex dynamics while in the 'inter-𝑛 mixing' predominant region, its dynamics behaves in a relatively stable way and the characteristic quantity 𝜉 shows a slight oscillation. Comparing the dynamics for hydrogen and barium, we find that the core effect makes the main contribution to the chaotic behavior in non-hydrogen atoms.

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Core effect on the diamagnetic spectrum of barium Rydberg states

Cited by 15 publications

References 41 publications

Non-linear spectral splitting of Rydberg sodium in external fields

Non-linear spectral splitting of Rydberg sodium in external fields

Nonlinear spectroscopy of barium in parallel electric and magnetic fields

Electron Dynamics of Atoms in Parallel Electric and Magnetic Fields

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