Time Delay in the Recoiling Valence Photoemission of Ar Endohedrally Confined in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:msub><mml:mi mathvariant="normal">C</mml:mi><mml:mn>60</mml:mn></mml:msub></mml:math>

Dixit, Gopal; Chakraborty, Himadri; Madjet, Mohamed

doi:10.1103/physrevlett.111.203003

Cited by 51 publications

(62 citation statements)

References 46 publications

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“…Phase and Wigner-Smith delay calculations by us [25] using the time-dependent local-density approximation (TDLDA) have recently agreed very well with the experiment on argon 3p photorecombination around the 3p CM [16]. Correlated delays in the emission between atom-fullerene hybrid electrons near Cooper-type minima in the Ar@C 60 molecule were unraveled using TDLDA [22]. For a different variety of spectral minima, which are abundant in the photoemission of cluster systems, TDLDA has probed attosecond structures in the emission delay [26].…”

Section: Introductionmentioning

confidence: 59%

Attosecond delay of xenon4dphotoionization at the giant resonance and Cooper minimum

2016

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A Kohn-Sham time-dependent local-density-functional scheme is utilized to predict attosecond time delays of xenon 4d photoionization that involves the 4d giant dipole resonance and Cooper minimum. The fundamental effect of electron correlations to uniquely determine the delay at both regions is demonstrated. In particular, for the giant dipole resonance, the delay underpins strong collective effect, emulating the recent prediction at C60 giant plasmon resonance [T. Barillot et al, Phys. Rev. A 91, 033413 (2015)]. For the Cooper minimum, a qualitative similarity with a photorecombination experiment near argon 3p minimum [S. B. Schoun et al., Phys. Rev. Lett. 112, 153001 (2014)] is found. The result should encourage attosecond measurements of Xe 4d photoemission.

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Section: Introductionmentioning

confidence: 59%

Attosecond delay of xenon4dphotoionization at the giant resonance and Cooper minimum

2016

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“….) (6.4) giving rise to a modulation of the photoionization cross section (Rüdel et al, 2002) as well as of the EWS time delay Pazourek et al, 2013;Dixit et al, 2013;Nagele et al, 2014;Deshmukh et al, 2014). These modulations bear close resemblance to the extended xray absorption fine structure (EXAFS; Sayers et al, 1971;Stern and Heald, 1983;Ito et al, 2004) by the local crystallographic environment near an absorption site in condensed matter.…”

Section: Time-resolved Photoionization Of Moleculesmentioning

confidence: 87%

“…The situation is strikingly different for many-electron atoms. First experiments were performed for rare gas atoms (Schultze et al, 2010;Klünder et al, 2011;Guénot et al, 2012), the results of which have led to a flurry of theoretical investigations (Schultze et al, 2010;Kheifets and Ivanov, 2010;Komninos et al, 2011;Nagele et al, 2011Nagele et al, , 2012Nagele et al, , 2014Baggesen and Madsen, 2011;Zhang and Thumm, 2010;Ivanov and Smirnova, 2011;Dahlström et al, 2012bDahlström et al, , 2013Dahlström et al, , 2012aPazourek et al, 2012a,b;Śpiewanowski and Madsen, 2012;Pazourek et al, 2013;Moore et al, 2011;Carette et al, 2013;Kheifets, 2013;Dixit et al, 2013;Feist et al, 2014;Saha et al, 2014;Wätzel et al, 2015). Yet, satisfactory agreement between theory and experiment is still outstanding and many open questions remain.…”

Section: Time-resolved Photoionization Of Many-electron Atomsmentioning

confidence: 99%

“…These can have either positive or negative sign, depending on whether the phase jump is positive (+ ) or negative (− ). Photoionization of the Ar 3 electron with one radial node features a Cooper minimum at a photon energy XUV ≈ 45 eV already at the Hartree-Fock-level (Amusia, 1990;Starace, 2006) while strong 3 -3 intershell correlations are responsible for a deep Cooper minimum in the Ar 3 photoionization cross section near 42 eV (Dahlström et al, 2012a;Kheifets, 2013;Carette et al, 2013;Dixit et al, 2013;Dahlström and Lindroth, 2014;Saha et al, 2014). These photon energies are within reach of attosecond XUV pulses and have been investigated by combining an attosecond pulse train with an IR field.…”

Section: Time-resolved Photoionization Of Many-electron Atomsmentioning

confidence: 99%

“…Timing of the photoelectron emission from the central atom offers now to probe a multitude of environment-specific contributions to the time shift. For outer-shell electron emission, e.g., the 3 electron of argon, hybridization with the valence electrons of the C 60 shell strongly modifies the EWS time delay relative to that of the free atom (Dixit et al, 2013 (Kilcoyne et al, 2010;Dolmatov and Manson, 2008). The wavelength of the outgoing electron dB may match the resonance condition in terms of the radius of the fullerene shell 0 , = 2 0 , ( = 1, 2, .…”

Section: Time-resolved Photoionization Of Moleculesmentioning

confidence: 99%

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Attosecond chronoscopy of photoemission

2015

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Recent advances in the generation of well characterized sub-femtosecond laser pulses have opened up unpredicted opportunities for the real-time observation of ultrafast electronic dynamics in matter. Such attosecond chronoscopy allows a novel look at a wide range of fundamental photophysical and photochemical processes in the time domain, including Auger and autoionization processes, photoemission from atoms, molecules, and surfaces, complementing conventional energy-domain spectroscopy. Attosecond chronoscopy raises fundamental conceptual and theoretical questions as which novel information becomes accessible and which dynamical processes can be controlled and steered. These questions are currently a matter of lively debate which we address in this review. We will focus on one prototypical case, the chronoscopy of the photoelectric effect by attosecond streaking. Is photoionization instantaneous or is there a finite response time of the electronic wavefunction to the photoabsorption event? Answers to this question turn out to be far more complex and multi-faceted than initially thought. They touch upon fundamental issues of time and time delay as observables in quantum theory. We review recent progress of our understanding of time-resolved photoemission from atoms, molecules, and solids. We will highlight the unresolved and open questions and we point to future directions aiming at the observation and control of electronic motion in more complex nanoscale structures and in condensed matter.

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XUV Attosecond Photoionization and Related Ultrafast Processes in Diatomic and Large Molecules

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Ultrafast Dynamics Driven by Intense Light Pulses

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The properties of matter are ultimately determined by its electronic structure. A suitable perturbation of the electrons' distribution from its equilibrium configuration in a system such as an atom, a molecule, or a solid, can therefore initiate certain dynamical processes. Intense and ultrashort light pulses are ideal tools for that purpose as their electric fields couple directly to the electrons. Therefore, they are not only able to distort the equilibrium electron distribution but, even allow driving a system on sub-femtosecond timescales with the light's Petahertz field-oscillations. This has been realized first in experiments that studied atoms in strong laser fields some 25 years ago. These experiments revealed a wealth of fundamentally important phenomena that are strictly timed to the laser-field oscillations such as the release of electrons by tunneling through the field-distorted Coulomb binding potential, or field-driven (re-)collisions of the released electrons with the atomic ion. The latter, in turn, led to the discovery of a range of essential secondary processes such as the generation of very high orders of harmonics of the driving light with photon energies that can extend into the X-ray range. Since then, thanks to a true revolution in laser technology, tremendous progress has been made in the field. Laser science has now reached a level of perfection where it is possible to produce intense light pulses with durations down to a single oscillation cycle and with virtually arbitrary evolution of the electric field in a wide range of frequencies. The availability of such field transients enabled a number of exciting possibilities, such as control over the breakage of selected chemical bonds in molecules by directly driving the molecular valence electrons that actually form the bond, or the production of coherent attosecond pulses in the soft X-ray wavelength range that can be used for probing or initiating dynamics on time-intervals during which the electronic distribution in the system under study stays essentially frozen. The recent years have seen a particularly vivid progress in the research of using ultrashort intense light pulses for controlling and probing ultrafast dynamics. On the one hand, a number of groups have extended the research field to systems with a much increased complexity and have studied and controlled field-induced dynamics in large polyatomic molecules, cluster complexes, bio-matter, nanoparticles and crystals, and also in condensed phase systems such as solid surfaces, v

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Time Delay in the Recoiling Valence Photoemission of Ar Endohedrally Confined inC60

Cited by 51 publications

References 46 publications

Attosecond delay of xenon4dphotoionization at the giant resonance and Cooper minimum

Attosecond delay of xenon4dphotoionization at the giant resonance and Cooper minimum

Attosecond chronoscopy of photoemission

XUV Attosecond Photoionization and Related Ultrafast Processes in Diatomic and Large Molecules

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