Quantum and semiclassical phase-space dynamics of a wave packet in strong fields using initial-value representations

Zagoya, Carlos; Wu, Jie; Rontó, Miklós; Shalashilin, Dmitrii V.; Faria, C. Figueira de Morisson

doi:10.1088/1367-2630/16/10/103040

Cited by 35 publications

(73 citation statements)

References 70 publications

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“…The initial spread of the electronic wave packet has been shown to be necessary for a good quantitative agreement with the TDSE in the context of high-order harmonic generation (HHG) [53][54][55][56]. This initial spread seems to be very important for strong-field ionization as well, as recent phase-space studies revealed that orbit-based methods that incorporate this spread exhibit a nearly quantitative agreement with the TDSE, even if tunnel ionization is not properly accounted for [57]. In addition, in the very low-energy region of the spectra, the CQSFA simulation exhibits a marked discrepancy with respect to the TDSE result.…”

Section: Resultsmentioning

confidence: 99%

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Near-threshold photoelectron holography beyond the strong-field approximation

Lai¹,

Yu²,

Huang³

et al. 2017

Phys. Rev. A

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We study photoelectron angular distributions (PADs) near the ionization threshold with a newly developed Coulomb quantum-orbit strong-field approximation (CQSFA) theory. The CQSFA simulations exhibit an excellent agreement with the result from the time-dependent Schrödinger equation. We show that the low-energy fan-shaped pattern in the PADs corresponds to a subcycle time-resolved holographic structure and stems from the significant influence of the Coulomb potential on the phase of the forward-scattered electron trajectories, which affects different momenta and scattering angles unequally. Our work provides a direct explanation of how the fan-shaped structure is formed, based on the quantum interference of direct and forward-scattered orbits. Moreover, our work shows that the fan-shaped pattern can be used to extract information on the target structure, as the number of fringes in the PADs depends strongly on the symmetry of the electronic bound state.

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Section: Resultsmentioning

confidence: 99%

“…This may be due to the initial momentum and position spread that exists for the TDSE, but is absent for the CQSFA. In fact, recent studies on HHG [53][54][55][56] and strong-field ionization [57] indicate that this spread is necessary for a quantitative agreement with the TDSE.…”

Section: Discussionmentioning

confidence: 99%

Near-threshold photoelectron holography beyond the strong-field approximation

Lai¹,

Yu²,

Huang³

et al. 2017

Phys. Rev. A

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“…Wigner functions have been widely employed in quantum optics and quantum information, but are underused in strong-field and attosecond physics. There are however studies of ionisation [18,40,43,44], rescattering [45,46] and entanglement [47] in this context. In strong-field ionisation, seminal studies [43] for a zero-range potential in a static field identified a tail that could be associated with a classical tunnelling trajectory far from the core region, and with tunnel ionisation close to the core.…”

Section: Introductionmentioning

confidence: 99%

Quantum bridges in phase space: interference and nonclassicality in strong-field enhanced ionisation

2019

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We perform a phase-space analysis of strong-field enhanced ionisation in molecules, with emphasis on quantum-interference effects. Using Wigner quasi-probability distributions and the quantum Liouville equation, we show that the momentum gates reported in a previous publication (Takemoto and Becker 2011 Phys. Rev. A 84 023401) may occur for static driving fields, and even for no external field at all. Their primary cause is an interference-induced bridging mechanism that occurs if both wells in the molecule are populated. In the phase-space regions for which quantum bridges occur, the Wigner functions perform a clockwise rotation whose period is intrinsic to the molecule. This evolution is essentially non-classical and non-adiabatic, as it does not follow equienergy curves or field gradients. Quasi-probability transfer via quantum bridges is favoured if the electron's initial state is either spatially delocalised, or situated at the upfield molecular well. Enhanced ionisation results from the interplay of this cyclic motion, adiabatic tunnel ionisation and population trapping. Optimal conditions require minimising population trapping and using the bridging mechanism to feed into ionisation pathways along the field gradient.

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“…As mentioned earlier, this reordering results in changes to the effective potential, giving a shallower potential than the form in coordinate representation such as that used in [42]. The kinetic energy term of the Hamiltonian is obtained through operator reordering and the potential terms through integration with equation (1).…”

Section: Modelmentioning

confidence: 99%

“…A similar version of the CCS method to that reported here has been used previously in Ref. [42] for the study of quantum dynamics in phase space. In Section II we provide the necessary theory in order to understand our results including an overview of the CCS method and its governing equations (sections II A and II B), a description of the theoretical model used to show the efficacy of the CCS method for generating HHG spectra (section II C) and a description of the necessary modifications made to the CCS method in order to model this system (section II D).…”

Section: Introductionmentioning

confidence: 99%

Coupled-coherent-states approach for high-order harmonic generation

Symonds

Rontó

et al. 2015

Phys. Rev. A

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In this paper we report a version of the Coupled Coherent States (CCS) method which is able to accurately compute the HHG spectrum of an electron in a laser field in one dimension by the use of trajectory-guided grids of Gaussian wavepackets. It is shown that by periodic re-projection of the wavefunction and dynamically altering the basis set size, the method can account for a wavefunction which spreads out to cover a large area in phase space while still keeping computational expense low. The HHG spectra obtained show good agreement with those from a time dependent Schrödinger equation solver. We show also that the part of the wavefunction which is responsible for HHG moves along a periodic orbit which is far from that of classical motion. Although this paper is a proof of principle and therefore focussed on a simple one-dimensional system, future generalisations for the multi-electron case are discussed.

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Quantum and semiclassical phase-space dynamics of a wave packet in strong fields using initial-value representations

Cited by 35 publications

References 70 publications

Near-threshold photoelectron holography beyond the strong-field approximation

Near-threshold photoelectron holography beyond the strong-field approximation

Quantum bridges in phase space: interference and nonclassicality in strong-field enhanced ionisation

Coupled-coherent-states approach for high-order harmonic generation

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