Excitation of Rydberg wave packets in the tunneling regime

Piraux, Bernard; Mota-Furtado, F.; O’Mahony, Patrick; Galstyan, A.; Popov, Yu. V.

doi:10.1103/physreva.96.043403

Cited by 30 publications

(26 citation statements)

References 30 publications

(43 reference statements)

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“…Since the energies of the Rydberg states are near the threshold so that their Stark shifts are all close to the Stark shift U p of the continuum, multiphoton resonance between the Rydberg and the initial states occurs at intensities that are separated by ∆U p = ω [1]. In addition, the dipole selection rule only allows even-order (odd-order) multiphoton transitions between states of equal (opposite) parity, which gives rise to a ∆U p = 2 ω separation between consecutive peaks for a transition between two states with specified parity [17,19]. Apparently, these features are beyond the scope of the semiclassical picture of the RSE.…”

Section: Comparison Of Tdse and Model Calculationsmentioning

confidence: 96%

Quantum dynamics of atomic Rydberg excitation in strong laser fields

Hao

et al. 2019

Opt. Express

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Neutral atoms have been observed to survive intense laser pulses in high Rydberg states with surprisingly large probability. Only with this Rydberg-state excitation (RSE) included is the picture of intense-laser-atom interaction complete. Various mechanisms have been proposed to explain the underlying physics. However, neither one can explain all the features observed in experiments and in time-dependent Schrödinger equation (TDSE) simulations. Here we propose a fully quantummechanical model based on the strong-field approximation (SFA). It well reproduces the intensity dependence of RSE obtained by the TDSE, which exhibits a series of modulated peaks. They are due to recapture of the liberated electron and the fact that the pertinent probability strongly depends on the position and the parity of the Rydberg state. We also present measurements of RSE in xenon at 800 nm, which display the peak structure consistent with the calculations.PACS numbers:

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Section: Comparison Of Tdse and Model Calculationsmentioning

confidence: 96%

Quantum dynamics of atomic Rydberg excitation in strong laser fields

Hao

et al. 2019

Opt. Express

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“…Theoretical analysis of the angular momentum distribution in the populated Rydberg states is less advanced. Predictions of Floquet theory for a monochromatic laser field [35] and results of numerical calculations for laser pulses with a trapezoidal envelope [32] yield that the angular momentum of the excited Rydberg states has the same parity as N p − 1, where N p is the minimum number of photons needed to ionize the atom. Furthermore, the angular quantum number of the states with the largest population in numerical calculations [9,10,32] agrees well with semiclassical estimations [36], initially performed for low-energy angular resolved photoelectron distributions.…”

Section: Introductionmentioning

confidence: 99%

“…Recent theoretical studies of the excitation mechanism in strong fields mainly consider the distribution of the population as a function of the principal quantum number of the excited states [9,10,25,31,32]. It was shown that the modulation of the excitation probability is related to the channel closing effect [9,10,32,35]. The latter phenomenon occurs at threshold intensities at which the absorption of one more photon is needed to ionize the atom due to the shift of the ionization threshold by the ponderomotive energy.…”

Section: Introductionmentioning

confidence: 99%

Angular momentum distribution in Rydberg states excited by a strong laser pulse

et al. 2018

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We study the excitation to Rydberg states in the interaction of the hydrogen atom with a short strong laser pulse. Utilizing solutions of the time-dependent Schrödinger equation we find that the parity of the populated angular momentum states agrees with the selection rules for multiphoton resonant absorption at low intensities, if the pulse length is not too short. In contrast, the parity effect cannot be observed for ultrashort pulses as well as for long pulses at high intensities. We further identify signatures of the population in the excited states via the line emissions from the populated np states after the end of the pulse exhibiting the parity effect.

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“…As briefly described in [25], our numerical method to solve the TDSE is based on a spectral method, which consists in expanding the total wave function in a basis composed of products of spherical harmonics and complex radial Coulomb Sturmian functions. These Sturmian functions depend on a nonlinear parameter which allows one to monitor the region of the bound state spectrum we want to describe accurately.…”

Section: Numerical Aspectsmentioning

confidence: 99%

“…This is the objective of the present paper. Several attempts have been made to study this problem by solving numerically the time dependent Schrödinger equation (TDSE) [20,21,25]. However, such a calculation is tremendously difficult and still out of reach in the limit where the frequency tends to zero.…”

Section: Introductionmentioning

confidence: 99%

Static field limit of excitation probabilities in laser-atom interactions

Galstyan

Shablov

Popov

et al. 2019

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

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We consider the interaction of atomic hydrogen, in its ground state, with an electromagnetic pulse whose duration is fixed in terms of the number of optical cycles. We study the probability of excitation of the atom in the static field limit i.e. for field frequencies going to zero. Despite the fact that the well known Born-Fock adiabatic theorem is valid only for a system whose energy spectrum is discrete, we show that it is still possible to use this theorem to derive, in the low frequency limit, an analytical formula which gives the probability of transition to any excited state of the atom as a function of the field intensity, the carrier envelope phase and the number of optical cycles within the pulse. The results for the probability of excitation to low-lying excited states, obtained with this formula, agree with those we get by solving the time dependent Schrödinger equation. The domain of validity is discussed in detail.

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Excitation of Rydberg wave packets in the tunneling regime

Cited by 30 publications

References 30 publications

Quantum dynamics of atomic Rydberg excitation in strong laser fields

Quantum dynamics of atomic Rydberg excitation in strong laser fields

Angular momentum distribution in Rydberg states excited by a strong laser pulse

Static field limit of excitation probabilities in laser-atom interactions

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