Attosecond real-time observation of electron tunnelling in atoms

Uiberacker, M.; Uphues, Thorsten; Schultze, Martin; Verhoef, A. J.; Yakovlev, Vladislav S.; Kling, Matthias F.; Rauschenberger, J.; Кабачник, Н. М.; Schröder, H.; Lezius, M.; Kompa, K. L.; Müller, H. G.; Vrakking, Marc J. J.; Hendel, Stefan; Kleineberg, Ulf; Heinzmann, Ulrich; Drescher, Markus; Krausz, Ferenc

doi:10.1038/nature05648

Cited by 857 publications

(599 citation statements)

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“…On the one hand, ultrahigh light intensities provided by multi-terawatt femtosecond lasers can be used to drive collective electron motion in plasmas up to the 0.1-1 gigaelectronvolt energy range [1], opening the way to very compact laser-based particle accelerators for nuclear and medical applications [2]. On the other hand, controlled few-cycle light waves can be used at moderate intensities to drive and probe the attosecond dynamics of few-electron motion in atoms [3,4,5,6], molecules [7,8] and condensed matter [9,10] -with typical energies * These authors contributed equally to this work. …”

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confidence: 99%

Attosecond control of collective electron motion in plasmas

et al. 2012

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Today, light fields of controlled and measured waveform can be used to guide electron motion in atoms and molecules with attosecond precision. Here, we demonstrate attosecond control of collective electron motion in plasmas driven by extreme intensity (≈ 10 18 W/cm 2 ) light fields.Controlled few-cycle near-infrared light waves are tightly focused at the interface between vacuum and a solid-density plasma, where they launch and guide subcycle motion of electrons from the plasma with characteristic energies in the multi-kiloelectronvolt range -two orders of magnitude more than what has been achieved so far in atoms and molecules. Basic spectroscopy of the coherent extreme ultraviolet radiation emerging from the light-plasma interaction allows us to probe this collective motion of charge with sub-100-attosecond resolution. This is an important step towards attosecond control of charge dynamics in laser-driven plasma experiments.Two major trends can nowadays be identified in the interaction of ultrashort laser pulses with matter. On the one hand, ultrahigh light intensities provided by multi-terawatt femtosecond lasers can be used to drive collective electron motion in plasmas up to the 0.1-1 gigaelectronvolt energy range [1], opening the way to very compact laser-based particle accelerators for nuclear and medical applications [2]. On the other hand, controlled few-cycle light waves can be used at moderate intensities to drive and probe the attosecond dynamics of few-electron motion in atoms [3,4,5,6], molecules [7,8] and condensed matter [9,10] -with typical energies * These authors contributed equally to this work. 1ranging between tens to a few hundred electronvolts [11]. Merging these two trends, i.e. using tailored waveforms of extreme intensity light to steer the collective motion of high-energy plasma electrons, will open brand new perspectives for imaging ultrafast charge dynamics during extreme intensity laser-plasma interactions. First experiments have already highlighted the need for waveform control when trying to reproducibly guide attosecond electronic processes in plasmas with intense few-cycle light fields [12]. For the first time, we use fully controlled few-cycle near-infrared (NIR) light fields of extreme intensity (10 18 W/cm 2 ) to reproducibly launch and probe collective electron motion at the interface between vacuum and a solid-density plasma with attosecond precision (Fig. 1a-b). Light-driven plasma mirrorsWhen an intense femtosecond laser pulse interacts with a solid, its rising edge strongly ionizes the surface atoms, creating a layer of plasma with near-solid electronic density (∼ 10 23 cm −3 ), which becomes highly reflectivea so-called plasma mirror -for light at wavelengths greater than a few tens of nanometers [13,14,15,16,17].During the interaction with the pulse, the plasma layer can only expand by a small fraction of the optical laser wavelength, λL, which leads to the formation of a very sharp interface with vacuum extending over a distance λL (Fig. 1b), typically of the order o...

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Attosecond control of collective electron motion in plasmas

et al. 2012

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“…The relaxation pathways of the created vacancy via single (A1) and double (A2) Auger decay involving several intermediate states were directly observed by detecting 4d and two Auger electrons in coincidence [30]. Time constants for the Auger decay of τ A1 = 6.0 ± 0.7 fs and τ A2 = 30.8 ± 1.4 fs leading to Xe 2+ and Xe 3+ final states with two or three vacancies in the outer 5p shell, respectively, are known with high precision from time-domain studies [31] and energy-resolved measurements [32]. Averaged Xe 3+ and Xe 4+ ion yields (grey opened circles) as a function of the time delay are plotted in Figure 10 (Figure 10(c) and [31]).…”

Section: Exploring the Intrinsic Temporal Resolution Of Flash With Thmentioning

confidence: 99%

“…Time constants for the Auger decay of τ A1 = 6.0 ± 0.7 fs and τ A2 = 30.8 ± 1.4 fs leading to Xe 2+ and Xe 3+ final states with two or three vacancies in the outer 5p shell, respectively, are known with high precision from time-domain studies [31] and energy-resolved measurements [32]. Averaged Xe 3+ and Xe 4+ ion yields (grey opened circles) as a function of the time delay are plotted in Figure 10 (Figure 10(c) and [31]). The electron dynamics leading to the transient Xe 4+ ion yield is governed by short-lived intermediate excited states (Figure 10(d) and τ A2 in [31]) leading to a fast decrease for positive time delays.…”

Section: Exploring the Intrinsic Temporal Resolution Of Flash With Thmentioning

confidence: 99%

“…Averaged Xe 3+ and Xe 4+ ion yields (grey opened circles) as a function of the time delay are plotted in Figure 10 (Figure 10(c) and [31]). The electron dynamics leading to the transient Xe 4+ ion yield is governed by short-lived intermediate excited states (Figure 10(d) and τ A2 in [31]) leading to a fast decrease for positive time delays. Transient changes of the ion yields are observed within a noticeably broad time window (Figure 10(a) and (b)).…”

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confidence: 99%

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Time-diagnostics for improved dynamics experiments at XUV FELs

Drescher

Frühling

Krikunova

et al. 2010

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

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Abstract. Significantly structured and fluctuating temporal profiles of pulses from SASE free electron lasers as well as their unstable timing requires time-diagnostics on a single-shot basis. The duration and structure of XUV pulses from the Free Electron Laser in Hamburg (FLASH) are becoming accessible using a variation of the streak camera principle, where photoemitted electrons are energetically streaked in the electric field component of a terahertz electromagnetic wave. The timing with respect to an independently generated laser pulse can be measured in an XUV/laser cross-correlator, based on a non-collinear superposition of both pulses on a solid state surface and detection of XUV-induced modulations of its reflectivity for visible light. Sorting of data according to the measured timing dramatically improves the temporal resolution of an experiment sampling the relaxation of transient electronic states in xenon after linear-as well as non-linear excitation with intense XUV pulses from FLASH.

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“…Ultrashort few-cycle laser pulses have a number of important applications, such as coherent control of ultrafast reaction, detection of atomic and molecular dynamics [2][3][4][5] and attosecond pulse generation [6][7][8][9][10][11]. Nonlinear optics with few-cycle pulses has many novel aspects.…”

Section: Introductionmentioning

confidence: 99%

Carrier-envelope phase-dependent transmitted spectra in inversion-asymmetric media with permanent dipole moments

Yang¹,

Xia²,

Zhang³

et al. 2009

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

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We investigate the transmitted spectra of a few-cycle ultrashort pulse in an inversion-asymmetric medium with a permanent dipole moment (PDM). Our results show that even-order harmonics can be generated in this medium. Moreover, the generated even-order harmonics depend strongly on the carrier-envelope phase (CEP) of initial incident few-cycle ultrashort pulses. Physical analysis of the re-emitted spectra of the medium reveals that the CEP-dependent spectral effect is originated from the inversion-asymmetric structure and the corresponding PDM effects: two-photon transition dominates in the nonlinear process and further induces the generations of the even-order harmonics. Furthermore, the orientation relation between the electric field peak of the pulse and the PDM results in even-order harmonic generations depending on the CEP.

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Attosecond real-time observation of electron tunnelling in atoms

Cited by 857 publications

References 29 publications

Attosecond control of collective electron motion in plasmas

Attosecond control of collective electron motion in plasmas

Time-diagnostics for improved dynamics experiments at XUV FELs

Carrier-envelope phase-dependent transmitted spectra in inversion-asymmetric media with permanent dipole moments

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