Excited Ions in Intense Femtosecond Laser Pulses: Laser-Induced Recombination

Williams, Ian D.; Wood, James B.; Suresh, M.; Bryan, William A.; Stebbings, Sarah L.; English, E. M. L.; Calvert, C. R.; Srigengan, B.; Divall, E. J.; Hooker, C. J.; Langley, A. J.; Newell, W R

doi:10.1103/physrevlett.99.173002

Cited by 8 publications

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References 20 publications

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“…The highest peak focal intensity for both pulse durations is 10 16 W/cm 2 and lower intensities are sampled by crossing the ion beam with the laser away from the center of the laser focus, that is, shifting the laser focus along its propagation direction while keeping the ion beam position fixed (e.g., Refs. [32][33][34]), a variant of the intensity selective scanning (ISS) method [35,36].…”

Section: Experimental Methodsmentioning

confidence: 99%

Measurements of intense ultrafast laser-driven D3+fragmentation dynamics

et al. 2012

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Experiments on the triatomic hydrogen molecular ion in intense ultrashort laser pulses are important for understanding the fundamentals of polyatomic molecular dynamics and for providing a benchmark for theory.Here we extend our earlier measurements [Phys. Rev. Lett. 103, 103004 (2009)] to provide a comprehensive picture of D 3 + fragmentation in 7-and 40-fs, 790-nm laser pulses at intensities up to 10 16 W/cm 2 . Our measurements incorporate two-and three-body coincidence three-dimensional momentum imaging involving a crossed-beam setup. We provide details of the relative fragmentation rates of all the possible breakup channels as a function of intensity, as well as kinetic energy release and angular distributions.

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Section: Experimental Methodsmentioning

confidence: 99%

Measurements of intense ultrafast laser-driven D3+fragmentation dynamics

et al. 2012

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“…This has been used to resolve attosecond timescale motion of molecular dynamics [11][12][13][14]. Electron recombination with the parent ion has been observed by detecting the high-harmonic photons emitted in this process (see, e.g., [15]) or through detection of the particles following the recombination event [16]. Electron recombination is the foundation of the modern era of optical attosecond science [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Frustrated tunneling ionization during laser-induced D2fragmentation: Detection of excited metastable D*atoms

et al. 2011

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In a recent Letter, Manschwetus et al. [Phys. Rev. Lett. 102, 113002 (2009)] reported evidence of electron recapture during strong-field fragmentation of H 2 -explained using a frustrated tunneling ionization model. Unusually, the signature of this process was detection of excited H * atoms. We report here an extensive study of this process in D 2 . Our measurements encompass a study of the pulse duration, intensity, ellipticity, and angular distribution dependence of D * formation. While we find that the mechanism suggested by Manschwetus et al. is consistent with our experimental data, our theoretical work shows that electron recollision excitation cannot be completely ruled out as an alternative mechanism for D * production.

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“…From the experimental evidence, we conclude that the origin of the feature is due to frustrated tunnelling ionization, the first observation of this mechanism in a polyatomic system. Furthermore, we unravel evidence of frustrated tunnelling ionization in dissociation, both two-body breakup to D + D + 2 and D + + D 2 , and three-body breakup to D + + D + D. Gesellschaft processes involving either elastic scattering [6][7][8], inelastic scattering [9, 10], or electron-ion recombination [11]. These phenomena have led to the birth of new areas of research such as high-harmonic generation and attosecond science [12][13][14][15], laser-driven electron diffraction imaging [5][6][7][8], molecular orbital tomography [16,17] and electron wavepacket probing of molecular dynamics [18-21]-naming only a few.Related to the electron recollision process, recently Nubbemeyer et al [22] reported a new phenomenon dubbed frustrated tunnelling ionization (FTI).…”

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Frustrated tunnelling ionization during strong-field fragmentation of D₃⁺

et al. 2012

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We reveal surprisingly high kinetic energy release in the intense-field fragmentation of D + 3 to D + + D + + D with 10 16 W cm −2 , 790 nm, 40 fs (and 7 fs) laser pulses. This feature strongly mimics the behaviour of the D + + D + + D + channel. From the experimental evidence, we conclude that the origin of the feature is due to frustrated tunnelling ionization, the first observation of this mechanism in a polyatomic system. Furthermore, we unravel evidence of frustrated tunnelling ionization in dissociation, both two-body breakup to D + D + 2 and D + + D 2 , and three-body breakup to D + + D + D. Gesellschaft processes involving either elastic scattering [6][7][8], inelastic scattering [9, 10], or electron-ion recombination [11]. These phenomena have led to the birth of new areas of research such as high-harmonic generation and attosecond science [12][13][14][15], laser-driven electron diffraction imaging [5][6][7][8], molecular orbital tomography [16,17] and electron wavepacket probing of molecular dynamics [18-21]-naming only a few.Related to the electron recollision process, recently Nubbemeyer et al [22] reported a new phenomenon dubbed frustrated tunnelling ionization (FTI). Demonstrated originally in strong-field ionization of helium, Nubbemeyer et al showed that an electron wavepacket that starts to tunnel away from the core in an intense laser field, but fails to acquire sufficient drift momentum to escape the attractive potential of the remaining He + ion, can be captured into an excited Rydberg orbital of the He atom-in effect 'frustrating' the tunnel ionization process. This process must occur during the laser pulse to conserve energy and momentum, most likely during the trailing edge, as the electron is gently decelerated over many laser cycles before being pulled into orbit.The same mechanism has been observed in the dissociative ionization of a few diatomic molecules (H 2 [23], D 2 [24], O 2 [25] and Ar 2 [26][27][28]). For such molecules, following ionization, an electron that is excited to the continuum and driven by the laser field tends to be captured to a Rydberg orbital of one of the two 'Coulomb-exploding' fragment ions. The signature of frustrated tunnelling in molecules is that, counterintuitively, the final kinetic energy release (KER) is similar to that of a Coulomb explosion event even though only one product fragment is charged while the other fragment is neutral [23].This description of FTI uses language, such as electron capture, that is usually reserved for discussions involving ionization. Throughout the paper we use this language for convenience. However, it does pose an interesting question in relation to the actual mechanism for FTI, that is,

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Excited Ions in Intense Femtosecond Laser Pulses: Laser-Induced Recombination

Cited by 8 publications

References 20 publications

Measurements of intense ultrafast laser-driven D3+fragmentation dynamics

Measurements of intense ultrafast laser-driven D3+fragmentation dynamics

Frustrated tunneling ionization during laser-induced D2fragmentation: Detection of excited metastable D*atoms

Frustrated tunnelling ionization during strong-field fragmentation of D₃⁺

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Excited Ions in Intense Femtosecond Laser Pulses: Laser-Induced Recombination

Cited by 8 publications

References 20 publications

Measurements of intense ultrafast laser-driven D3+fragmentation dynamics

Measurements of intense ultrafast laser-driven D3+fragmentation dynamics

Frustrated tunneling ionization during laser-induced D2fragmentation: Detection of excited metastable D*atoms

Frustrated tunnelling ionization during strong-field fragmentation of D3+

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Frustrated tunnelling ionization during strong-field fragmentation of D₃⁺