Using a passively stable attosecond beamline for relative photoemission time delays at high XUV photon energies

Jain, Arohi; Gaumnitz, Thomas; Kheifets, Anatoli; Wörner, Hans Jakob

doi:10.1364/oe.26.028604

Cited by 11 publications

(10 citation statements)

References 51 publications

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“…We hope that the present work will guide the new generation of RABBITT measurements accessing very large sideband orders and deeper atomic shells. These measurements have been reported in the literature very recently [7,14,15]. In heavier atoms and deeper atomic shells such as Xe 4d, the spin-orbit splitting effects become noticeable.…”

Section: Discussionsupporting

confidence: 57%

“…Recently, this technique has become angular resolved [11][12][13]. While the initial studies have been confined to a narrow photon energy range not exceeding 40 eV (24th harmonic of the fundamental radiation at λ 800 nm), the most recent experiments [7,14,15] extended this range above 100 eV. This has enabled the study of photoemission dynamics beyond the outer atomic shells and to probe the subvalent 4d shell of the Xe atom [14].…”

Section: Introductionmentioning

confidence: 99%

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Photoionization of Xe and Xe@C60 from the 4d shell in RABBITT fields

2018

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We consider photoemission from the 4d shell of the free Xe and encapsulated Xe@C 60 atoms by ionizing XUV and probing IR fields typical for a RABBITT (reconstruction of attosecond beating by interference of twophoton transitions) measurement. Our theoretical model is based on the numerical solution of the time-dependent Schrödinger equation in the single-active-electron approximation. The fullerene C 60 cage is represented by a finite-width well potential. We test our model against an analogous set of nonrelativistic [Phys. Rev. A 89, 053424 (2014)] and relativistic [Phys. Rev. A 96, 053407 ( 2017)] calculations for the 4d shell of Xe and Xe@C 60 driven by a continuous XUV field. Based on this verification, we make predictions for the total ionization probability, angular anisotropy β parameter, and the angular-dependent atomic time delay τ a from the threshold to several hundred eV of excess energy.

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Section: Discussionsupporting

confidence: 57%

Section: Introductionmentioning

confidence: 99%

Photoionization of Xe and Xe@C60 from the 4d shell in RABBITT fields

2018

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“…Parameters that were varied are the HHG phase-matching conditions, such as the xenon gas pressure and the IR intensity, the metallic filter (either Al or Sn), the electric extraction field in the COLTRIMS, and the magnetic field. The data were then analyzed for argon and CF 4 separately using a CVPCA, which has been introduced by Jordan and Wörner (35) and since then successfully used to extract phases in spectrally congested time-resolved electron spectra (48)(49)(50). The CVPCA is implemented as follows.…”

Section: Discussionmentioning

confidence: 99%

Attosecond interferometry of shape resonances in the recoil frame of CF ₄

et al. 2021

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Shape resonances play a central role in many areas of science, but the real-time measurement of the associated many-body dynamics remains challenging. Here, we present measurements of recoil frame angle-resolved photoionization delays in the vicinity of shape resonances of CF 4 . This technique provides insights into the spatiotemporal photoionization dynamics of molecular shape resonances. We find delays of up to ∼600 as in the ionization out of the highest occupied molecular orbital (HOMO) with a strong dependence on the emission direction and a pronounced asymmetry along the dissociation axis. Comparison with quantum-scattering calculations traces the asymmetries to the interference of a small subset of partial waves at low kinetic energies and, additionally, to the interference of two overlapping shape resonances in the HOMO-1 channel. Our experimental and theoretical results establish a broadly applicable approach to space-and time-resolved photoionization dynamics in the molecular frame.

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“…The delay difference between photoelectrons originating from the outermost p 3/2 and p 1/2 orbitals in Krypton and Xenon have been studied in Ref. [71,72], using the interferometric RABBITT technique. In Fig.…”

Section: Comparison With Experimentsmentioning

confidence: 99%

“…While RRPA theory was originally developed in the late seventies by Johnson and Cheng to describe one-photon ionization cross sections in heavy elements [69,70], the interest in such phenomena is revived by recent RABBIT experiments that have targeted heavy elements. Firstly, Jordan et al [71] and Jain et al [72] have compared photoelectrons from the fine-structure split valance orbitals: 4p j and 5p j with j = 1/2 and 3/2 of Krypton and Xenon atoms, respectively, and secondly, Jain et al [73] and Zhong et al [74], have compared photoelectrons from inner orbitals in Xenon, down to the 4d orbital. The 4d orbital is of special interest since it is known to posses a giant collective resonance in the photoionization cross section, as evidenced by MBPT in the early seventies by Amusia and Wendin [75,76].…”

Section: Introductionmentioning

confidence: 99%

Relativistic Two-photon Matrix Elements for Attosecond Delays

Lindroth¹,

Dahlström²,

Vinbladh³

2022

Preprint

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The theory of one-photon ionization and two-photon above-threshold ionization is formulated for applications to heavy atoms in attosecond science using the Dirac-Fock formalism. A direct comparison of the Wigner-Smith-Eisenbud delays for photoionization is made with delays from the Reconstruction of Attosecond Beating By Interference of Two-photon Transitions (RABBIT) method. Photoionization by an attosecond pulse train, consisting of monochromatic fields in the extreme ultraviolet range, is computed with many-body effects at the level of the Relativistic Random Phase Approximation (RRPA). Subsequent absorption and emission processes of infrared laser photons in RABBIT are evaluated using static ionic potentials as well as asymptotic properties of relativistic Coulomb functions. As expected, light elements, such as Argon, show negligible relativistic effects, while heavier elements, such a Krypton and Xenon, exhibit delays that depend on the fine-structure of the ionic target. The relativistic effects are notable close to ionization thresholds and Cooper minima with differences in fine-structure delays predicted to be as large as tens of attoseconds. The separability of relativistic RABBIT delays into a Wigner-Smith-Eisenbud delay and a universal continuum--continuum delay is studied with reasonable separability found for photoelectrons emitted along the laser polarization axis in agreement with prior non-relativistic results.

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Using a passively stable attosecond beamline for relative photoemission time delays at high XUV photon energies

Cited by 11 publications

References 51 publications

Photoionization of Xe and Xe@C60 from the 4d shell in RABBITT fields

Photoionization of Xe and Xe@C60 from the 4d shell in RABBITT fields

Attosecond interferometry of shape resonances in the recoil frame of CF ₄

Relativistic Two-photon Matrix Elements for Attosecond Delays

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Using a passively stable attosecond beamline for relative photoemission time delays at high XUV photon energies

Cited by 11 publications

References 51 publications

Photoionization of Xe and Xe@C60 from the 4d shell in RABBITT fields

Photoionization of Xe and Xe@C60 from the 4d shell in RABBITT fields

Attosecond interferometry of shape resonances in the recoil frame of CF 4

Relativistic Two-photon Matrix Elements for Attosecond Delays

Contact Info

Product

Resources

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Attosecond interferometry of shape resonances in the recoil frame of CF ₄