Dynamic Two-Center Interference in High-Order Harmonic Generation from Molecules with Attosecond Nuclear Motion

Baker, Sarah; Robinson, Joseph S.; Lein, Manfred; Chirilă, C. C.; Torres, Ricardo; Bandulet, H.; Comtois, D.; Kieffer, Jean‐Claude; Villeneuve, D. M.; Tisch, J. W. G.; Marangos, Jonathan P.

doi:10.1103/physrevlett.101.053901

Cited by 114 publications

(76 citation statements)

References 25 publications

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“…1) and τ (ω) is the recollision time. This approximation has the advantage that it applies to the contribution from the short trajectories [16], matching the conditions of the available experimental data [4,5]. We thus make a relatively simple SFA model, in which we take the amplitude as R independent and obtain the R dependence of the phase using Eq.…”

Section: A Strong-field-approximation Phase Modelmentioning

confidence: 99%

“…In recent years HHG of molecules has been studied for its potential to probe, with subfemtosecond temporal resolution, nuclear dynamics including vibration [3][4][5][6][7] and dissociation [7]. The foundation of these applications is the sensitivity of HHG emission to the nuclear geometry and motion.…”

Section: Introductionmentioning

confidence: 99%

“…The foundation of these applications is the sensitivity of HHG emission to the nuclear geometry and motion. So far, the involvement of multiple molecular orbitals [6,7] and two-center interference [5,7] have been proposed as causes for the large oscillation of the HHG intensity in response to geometry changes in molecules. Further theoretical studies that detail the relation of molecular structure and dynamics with their HHG can contribute to the maturity of the application of HHG as a subfemtosecond molecular dynamics probe.…”

Section: Introductionmentioning

confidence: 99%

“…In a 2008 follow-up experiment, Baker et al [5] remeasured the isotope effect with different laser intensities and a longer pulse duration. They demonstrated that this model had to be extended by postulating a dynamic two-center interference effect, which is R dependent.…”

Section: Introductionmentioning

confidence: 99%

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Time-dependent density-functional-theory calculation of high-order-harmonic generation of H2

Chu

Groenenboom

2012

Phys. Rev. A

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The observation of the isotope effect in the high-order-harmonic generation (HHG) of H 2 presents a challenge for time-dependent density-functional-theory (TDDFT) methods, since this effect is related to the dynamics of the ion created in the tunneling ionization step of HHG and it depends on the harmonic order. As an initial step toward describing this effect within current computational capacity, we benchmark a method in which the nuclear and electronic degrees of freedom are separated and both treated quantum mechanically. For the electrons two TDDFT formalisms are adopted. Although the ion-dynamics effect is not described in our method, it reproduces the measured D 2 -to-H 2 HHG ratios up to the 25th harmonic when the 35th is the classical cutoff. Beyond the 25th harmonic, however, our results show substantial deviation and are sensitive to the laser intensity. A higher intensity reproduces the experimental results. Analysis reveals an R-dependent phase factor as the cause of the isotope effect in our calculation. We isolate this phase factor and propose a strong-field-approximation-phase model, which reproduces experimental data, including those for which the ion-dynamics model has to be further modified. We show that the model that we propose is intrinsically related to the ion-dynamics model. Our model provides a correction to the TDDFT approach when the ion-dynamics effect becomes significant. It also indicates that the isotope effect is not only a probe for the ion created by the external field but is ultimately a more useful probe for the ground-state nuclear wave function. For all molecules whose vertical ionization potential strongly depends on the nuclear geometry, HHG may serve as a sensitive ultrafast probe of nuclear dynamics.

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Section: A Strong-field-approximation Phase Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Time-dependent density-functional-theory calculation of high-order-harmonic generation of H2

Chu

Groenenboom

2012

Phys. Rev. A

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“…Exciting results have been obtained in recent years by using high-harmonic generation (HHG) [1,2] to probe molecular dynamics with subfemtosecond temporal resolution [3][4][5][6][7][8]. The sensitivity of HHG emission to molecular geometry and motion is the foundation for this application.…”

Section: Introductionmentioning

confidence: 99%

Role of resonance-enhanced multiphoton excitation in high-harmonic generation of N2: A time-dependent density-functional-theory study

Chu

Groenenboom

2013

Phys. Rev. A

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A minimum at ∼39 eV is observed in the high-harmonic-generation spectra of N 2 for several laser intensities and frequencies. This minimum appears to be invariant for different molecular orientations. We reproduce this minimum for a set of laser parameters and orientations in time-dependent density-functional-theory calculations, which also render orientation-dependent maxima at 23-26 eV. Photon energies of these maxima overlap with ionization potentials of excited states observed in photoelectron spectra. Time profile analysis shows that these maxima are caused by resonance-enhanced multiphoton excitation. We propose a four-step mechanism, in which an additional excitation step is added to the well-accepted three-step model. Excitation to a linear combination of Rydberg states c 4 1 + u and c 3 1 u gives rise to an orientation-invariant minimum analogous to the "Cooper minimum" in argon. When the molecular axis is parallel to the polarization direction of the field, a radial node goes through the atomic centers, and hence the Cooper-like minimum coincides with the minimum predicted by a modified two-center interference model that considers the de-excitation of the ion and symmetry of the Rydberg orbital.

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Perspektiven für das Verständnis fundamentaler Elektronenkorrelationen durch Attosekundenspektroskopie

Kraus

Wörner

2018

Angewandte Chemie

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Zusammenfassung Molekülorbitale sind ein sehr erfolgreiches Konzept in der Chemie zur Beschreibung der elektronischen Struktur von Molekülen. Diese Beschreibung ist jedoch unzureichend, wenn die Elektronen in Molekülen stark korreliert sind und nicht als unabhängige Teilchen behandelt werden können. Die Auswirkungen solcher Elektronenkorrelationen sind allgegenwärtig in der Spektroskopie innerer Valenzelektronen durch Ultraviolet-und Röntgenstrahlen, ausserdem können Elektronenkorrelationen Ladungswanderungen in Molekülen vorantreiben und sind verantwortlich für viele exotische Eigenschaften stark korrelierter Materialien. Zeitaufgelöste Spektroskopie mit Attosekundenzeitauösung kann im Allgemeinen Elektronendynamik in Echtzeit verfolgen und kann dadurch einen experimentellen Zugang zu Phänomenen erönen, welche durch Elektronenkorrelation vorangetrieben werden. Die Spektroskopie hoher Harmonischer im Speziellen verwendet die präzise zeitabgestimmte Rekollision von laser-beschleunigten Elektronen, um die elektronische Struktur und Dynamik des untersuchten Systems auf einer sub-Femtosekunden Zeitskala zu messen. In diesem Übersichtsartikel diskutieren wir die Möglichkeiten der Spektroskopie hoher Harmonischer, um Elektronendynamik in Molekülen zu verfolgen. Wir besprechen, wie die Spektroskopie hoher Harmonischer auf qualitative und quantitative Weise analysiert werden kann, um die detaillierte Elektronendynamik in Molekülen nach Ionisierung zu verfolgen. Diese Fortschritte machen die Spektroskopie hoher Harmonischer zu einer vielversprechenden Methode, um fundamentale Elektronenkorrelationen aufzudecken und experimentelle Daten zu komplexen Elektronendynamiken bereitzustellen. * peter.kraus@berkeley.edu † hwoerner@ethz.ch; www.atto.ethz.ch 1

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Dynamic Two-Center Interference in High-Order Harmonic Generation from Molecules with Attosecond Nuclear Motion

Cited by 114 publications

References 25 publications

Time-dependent density-functional-theory calculation of high-order-harmonic generation of H2

Time-dependent density-functional-theory calculation of high-order-harmonic generation of H2

Role of resonance-enhanced multiphoton excitation in high-harmonic generation of N2: A time-dependent density-functional-theory study

Perspektiven für das Verständnis fundamentaler Elektronenkorrelationen durch Attosekundenspektroskopie

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