Abstract
Strong-field laser–molecule interaction forms much of the basis for initiating and probing ultrafast quantum dynamics. Previous studies aimed at elucidating the origins of vibrational coherences induced by intense laser fields have been confined to diatomic molecules. Furthermore, in all cases examined to date, vibrational wave packet motion is found to be induced by R-selective depletion; wave packet motion launched by bond softening, though theoretically predicted, remains hitherto unobserved. Here we employ the exquisite sensitivity of femtosecond extreme ultraviolet absorption spectroscopy to sub-picometer structural changes to observe both bond softening-induced vibrational wave packets, launched by the interaction of intense laser pulses with iodomethane, as well as multimode vibrational motion of the parent ion produced by strong-field ionization. In addition, we show that signatures of coherent vibrational motion in the time-dependent extreme ultraviolet absorption spectra directly furnish vibronic coupling strengths involving core-level transitions, from which geometrical parameters of transient core-excited states are extracted.
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Introduction
Femtosecond intense laser–matter interaction1 has emerged as a powerful approach for unraveling the ultrafast quantum dynamics of molecules via processes such as high-order harmonic generation2, above-threshold ionization3, and laser-induced electron diffraction4. These phenomena have in turn been applied to, for example, the tomographic imaging of molecular orbitals5, 6, the investigation of attosecond electronic wave packet dynamics7,8,9, and the retrieval of transient molecular structures10,11,12. While many of these studies aim to elucidate electronic dynamics, it is important to realize that the intense laser–molecule interaction also inevitably triggers coherent vibrational motion, whose coupling to the electronic degrees of freedom will invariably affect the outcome and interpretation of experiments and theories that nominally seek to address electron dynamics13,14,15. Other factors that motivate the investigation of coherent vibrational dynamics in the strong-field regime include the prospect of employing intense laser fields to manipulate molecular dynamics16,17,18,19 and the identification of ion electronic states produced by strong-field ionization by measuring their vibrational quantum beat frequencies20.
Aside from the launching of vibrational wave packet dynamics in ions by strong-field ionization, the interaction of intense laser pulses with molecules can also generate vibrational coherences in the electronic ground state of neutral species. Two different mechanisms have been proposed: R-selective depletion21 (Fig. 1a) and bond softening22 (Fig. 1b). R-selective depletion arises from the dependence of the strong-field ionization rate on the nuclear coordinate, which yields, after depletion of the ground-state population by ionization, a vibrational probability density that is described by a non-stationary state. Within the quasi-static picture of bond softening, valid for low-frequency laser fields and high laser intensities, the field-induced distortion of the electronic ground-state potential drives the initially stationary vibrational probability density distribution away from its equilibrium position, hence initiating wave packet motion. Previous investigations of vibrational coherences induced on the electronic ground state by intense laser fields have identified R-selective depletion as the dominant mechanism for their generation23,24,25. In pioneering studies by Ullrich et al., for example, an initial cosinusoidal oscillation phase of (0.946 ± 0.001)π rad in the temporal evolution of the D2 bond length suggests the launching of the vibrational wave packet from the outer turning point of the D2 potential23. This observation is consistent with the larger ionization potential, and hence, lower ionization rate, for D–D bond lengths larger than the equilibrium bond length. Cosinusoidal phases approaching 0 mod π, indicative of R-selective depletion, are also observed for vibrational coherences generated in the electronic ground states of I2 24 and Br2 25. These studies beget the question as to whether vibrational wave packets can be created by bond softening. Furthermore, the generality of launching vibrational wave packets in the electronic ground state of polyatomic molecules by intense laser pulses remains to be established. The ability to harness intense laser fields to drive vibrational coherences would complement nonresonant impulsive stimulated Raman scattering, which operates in the perturbative limit at relatively low laser intensities26.
Here we employ femtosecond extreme ultraviolet (XUV) absorption spectroscopy27, 28 to elucidate the origins of multimode coherent vibrational motion induced by intense laser fields in neutral iodomethane (CH3I) and its parent ion (CH3I+). XUV absorption spectroscopy is uniquely suited to the present investigation due to its ability to distinguish, with electronic state resolution, the iodine (I) 4d core-level transitions of CH3I and CH3I+, as well as those of the atomic photofragments I and I+. In the case of the CH3I \(\tilde X\) \({}^1{A_1}\) electronic ground state, analysis of the spectral modulations induced by C–I stretching motion (v 3) yields the relative contributions of bond softening and R-selective depletion to the generation of the wave packet (Fig. 1c). In addition, wave packet motions along the C–I stretch (v 3) and CH3 umbrella (v 2) modes are observed in the CH3I+ \({\tilde X^ + } \;{}^2{E_{3/2}}\) parent ion. The results unambiguously show the existence of bond softening-induced wave packets and demonstrate the exquisite sensitivity of femtosecond XUV absorption spectroscopy to structural changes on the sub-picometer length scale. Furthermore, we show that XUV absorption probing of coherent vibrational dynamics allows the retrieval of structural parameters for transient core-excited states.
Results
Experimental results
The differential XUV absorption spectra collected as a function of pump-probe time delay is shown in Fig. 2a (see “Methods” and “Supplementary Methods” sections for details of the experimental set-up). The XUV absorption features in this energy range are assigned to transitions from the spin-orbit-split I 4d core level to the unoccupied valence orbitals with predominantly I 5p character. Pronounced spectral modulations as a function of time delay are observed in the region of the neutral CH3I ground-state bleach transitions (~50–53 eV) (see Supplementary Note 1), i.e., the I \(4{d_j} \to \sigma _{{\rm{C}} - {\rm{I}}}^*\) transitions29 (j = 3/2 or 5/2). The positive differential absorption signals observed in the ~46–49 eV range originate from the CH3I+ parent ion and the atomic I and I+ photoproducts of dissociative ionization30. The prominent peak centered at 47.0 eV can be assigned to the I \(4{d_{5/2}} \to e_{3/2}^{ - 1}\) transition of the CH3I+ \({\tilde X^ + }\;\;{}^2{E_{3/2}}\) parent ion, based on the energetic difference between the binding energies of the I 4d 5/2 core level31 and the e 3/2 valence level32 (\({E_{4{d_{5/2}}}} - {E_{{e_{3/2}}}} =\) 47.08 eV). Analysis of the appearance times of I and I+ reveals ultrafast dissociative ionization dynamics, which will be detailed in a subsequent report. Here we focus on the vibrational wave packet dynamics encoded in the I \(4{d_j} \to \sigma _{{\rm{C}} - {\rm{I}}}^*\) and \(4{d_{5/2}} \to e_{3/2}^{ - 1}\) transitions of CH3I and CH3I+, respectively.
Vibrational wave packet generation mechanism in neutral CH3I
The time-dependent spectral first-moment \(\langle {E_{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}}\left( t \right) \rangle\) computed about the I \(4{d_j} \to \sigma _{{\rm{C}} - {\rm{I}}}^*\) transition of neutral CH3I reflects strong-field-induced wave packet motion along the C–I stretching mode in its electronic ground state (Fig. 2b). Beyond the high-frequency oscillation, the presence of an envelope modulation suggests a fit to two oscillatory components, i.e., \(\langle {{E_{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}}( t )} \rangle = {\sum} {\langle {E_{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{( i )}( 0 )} \rangle } \cos [ {\omega _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{( i )}t + \phi _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{( i )}} ]\) (i = 1,2). The first component, with an initial phase of \(\phi _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{\left( 1 \right)} = -\)(0.49 ± 0.05)π rad, is consistent with bond softening-induced wave packet motion. Because the I \(4{d_j} \to \sigma _{{\rm{C}} - {\rm{I}}}^*\) transition energy monotonically decreases with C–I bond length R C−I (see Supplementary Note 2), it can be inferred that an initial displacement toward larger R C−I leads to ϕ = −π/2 rad (see Supplementary Notes 3 and 4); conversely, initial displacement toward smaller R C−I leads to ϕ = π/2 rad. Within the Floquet picture, the one- and two-photon dressing of the neutral ground state by the dissociative \({}^3{Q_{{0^ + }}}\left( {{A_1}} \right)\) state19, 33 results in the softening of the ground-state C–I potential (see Supplementary Note 5). In the quasi-static limit of laser–molecule interaction, the intense laser field distorts the neutral ground state potential along the C–I coordinate. Both pictures yield the same outcome: the equilibrium vibrational probability density is initially displaced toward larger R C−I by the intense laser field, hence launching wave packet motion that is characterized by \(\phi _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{\left( 1 \right)} = - \pi {\rm{/}}2\) rad (Fig. 1a). The excellent agreement between the oscillation frequency \(\omega _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{\left( 1 \right)} =\) 533 ± 1 cm–1 and the literature value for the fundamental v 3 frequency34 (533 cm–1) is consistent with the bond softening-induced wave packet motion being dominated by the coherent superposition of the vibrational ground state and the first-excited state.
The second component of \(\left\langle {{E_{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}}\left( t \right)} \right\rangle\) has an initial phase of \(\phi _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{\left( 2 \right)} = -\)(0.09 ± 0.12)π rad, indicative of wave packet motion launched by R-selective depletion from the outer turning point of the C–I potential (Fig. 1a) (see Supplementary Note 4). This observation can be rationalized by inspecting, in the vicinity of the equilibrium R C−I for CH3I, the energy gap between the spectroscopically reconstructed Morse potentials of the CH3I and CH3I+ electronic ground states as a function of R C−I (Fig. 3, top panel; see Supplementary Note 6 for the parameters of the Morse potentials). This energy gap corresponds to the vertical ionization potential of CH3I. Its steep decrease for C–I bond lengths shorter than the equilibrium value favors strong-field ionization at the inner turning point of the C–I potential, hence launching wave packet motion from the outer turning point with a \(\phi _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{\left( 2 \right)}\) value of 0 rad. The measured oscillation frequency of \(\omega _{{\rm{C}}{{\rm{H}}_3}{\rm{I}}}^{\left( 2 \right)} =\) 518 ± 3 cm–1, anharmonically shifted from the fundamental frequency of 533 cm–1, suggests a vibrational coherence that involves mainly the v = 2 and v = 3 levels of the v 3 mode35, whose estimated fractional populations at a vibrational temperature of 353 K are 0.0117 and 0.0014, respectively. The high-lying vibrational states dominate the R-selective depletion response because they possess higher probability densities near the turning points of the C–I potential, where strong-field ionization rates are larger.
Multimode coherent vibrational motion in CH3I+
Aside from the C–I stretching wave packet initiated in neutral CH3I by the intense laser field, the time-dependent spectral first-moment \(\langle {{E_{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}}( t )} \rangle\) computed about the dominant CH3I+ I 4d 5/2 → \(e_{3/2}^{ - 1}\) resonance at 47.0 eV reveals oscillatory components that can be assigned to the C–I stretching (v 3) and CH3 umbrella (v 2) modes of the \({\tilde X^ + }\;{}^2{E_{3/2}}\) state (Fig. 2c). The \(\left\langle {{E_{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}}\left( t \right)} \right\rangle\) time trace can be fit to a sum of two damped cosinusoidal oscillations, i.e., \(\langle {{E_{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}}( t )} \rangle = {\sum} {\langle {E_{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( i )}( 0 )} \rangle } \cos [ {\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( i )}t + \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( i )}} ]{e^{ - t/\tau _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( i )}}}\) (i = 1,2). The retrieved vibrational frequencies, \(\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 1 \right)} =\) 1253 ± 1 and \(\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)} =\) 475 ± 1 cm–1, match those reported for the v 2 (1257 cm–1) and v 3 (480 cm–1) modes, respectively36. The vibrational wave packets for both modes dephase with comparable damping times: \(\tau _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 1 \right)} =\) 1.8 ± 0.6 ps and \(\tau _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)} =\) 1.7 ± 0.4 ps. The simultaneous appearance of both v 2 and v 3 modes in the vibrational wave packet is noteworthy, given that previous studies of polyatomic molecular ions produced by strong-field ionization resolved wave packet motion only along a single vibrational coordinate37, 38.
The initial oscillation phase of \(\phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 1 \right)} = \) (0.13 ± 0.12)π rad for the v 2 mode suggests displacive excitation of the CH3 umbrella mode wave packet. Displacive excitation occurs when the Franck–Condon region accessed by vertical ionization is displaced from the equilibrium geometry, such that the ensuing structural rearrangement that accompanies equilibration leads to wave packet motion with an initial phase of 0 mod π rad39. In this case, displacive excitation of the v 2 mode is supported by the small, but nevertheless, significant difference in the H–C–I bond angles between the neutral39 and ion40, 41 species: 107.7° in CH3I vs. 108.3° in CH3I+. Interestingly, the measured oscillation phase \(\phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)}\) of (0.71 ± 0.05)π rad for the C–I stretching mode deviates, beyond error, from phase values that would be expected for wave packet dynamics induced by either displacive excitation (π rad) or bond softening (π/2 rad). One plausible explanation is the simultaneous launching of wave packets by both displacive excitation and bond softening, such that the overall oscillatory signal at \(\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)} = \) 475 cm–1 can be expressed as: \(\cos [ {\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 2 )}t + \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 2 )}} ] = \sin \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 2 )}\cos [ {\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 2 )}t + \pi /2} ] - \cos \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 2 )}\cos [ {\omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 2 )}t + \pi } ]\), where the terms with amplitude coefficients \(\sin \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)}\) and \( - \cos \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)}\) arise from bond softening and displacive excitation, respectively. A phase value of \(\phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)} = \) (0.71 ± 0.05)π rad gives an amplitude ratio of \( - \sin \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)}/\cos \phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 2 \right)} = \) 1.3 ± 0.1, which in turn suggests that bond softening dominates over displacive excitation. It is conceivable that the same intense laser pulse that drives strong-field ionization can also induce the softening of the C–I potential of the resultant CH3I+ ions. Displacive excitation, on the other hand, is supported by the different equilibrium C–I bond lengths of CH3I (2.132 Å)40 and CH3I+ (2.126 Å)41. R-selective depletion calculations that consider averaging over both thermal and laser intensity distributions confirm that the initial vibrational probability density created in the CH3I+ \({\tilde X^ + }\;{}^2{E_{3/2}}\) state indeed extends to larger R C−I compared to that of the v = 0 eigenstate (Fig. 3, bottom panel; see Supplementary Note 7 for details of simulations). It is remarkable that the decrease in equilibrium C–I bond length of 0.006 Å, representing a mere change of 0.3%, can yield a discernible modulation of the XUV transition energy. For comparison, vibrational wave packets42 or coherent phonons39 detected by optical pump-probe spectroscopy typically involve changes in bond lengths of a few percent. The enhanced sensitivity of femtosecond XUV absorption spectroscopy to structural changes originates from the highly repulsive nature of the core-hole-excited state, in this case, the I \(4d_{5/2}^{ - 1}\) state of CH3I+ (see Supplementary Note 2). Access to such a repulsive potential upon absorption of the XUV probe pulse allows small geometrical distortions to be mapped onto measurable shifts in XUV transition energies.
Retrieval of I 4d –1 core-excited state geometries
Aside from unraveling the mechanism of wave packet generation, quantitative analysis of the time-resolved XUV absorption spectra also provides insight into the nature of the I \(4d_{5/2}^{ - 1}\) core-excited state. The strength of the vibronic coupling between the CH3I+ I 4d 5/2 → \(e_{3/2}^{ - 1}\) XUV probe transition and the v 2 vibrational mode, as characterized by the Huang–Rhys factor43 S, is recovered from the oscillation amplitude via the relation \(\langle {E_{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 1 )}( 0 )} \rangle = 2\lambda = 2\hbar \omega _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 1 )}S\), where λ is the reorganization energy44 (Fig. 4). (Note that the dissociative nature of the I \(4d_{5/2}^{ - 1}\) core-excited state potential along the C–I stretch coordinate precludes the same analysis from being performed for the v 3 mode.) The amplitude \(\langle {E_{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{( 1 )}( 0 )} \rangle =\) (2.6 ± 0.2)×10–3 eV therefore yields a Huang–Rhys factor of (8.3 ± 0.7) × 10–3, signifying weak vibronic coupling. Furthermore, combining the dimensionless displacement of \(\Delta = \sqrt {2S} = 0.13 \pm 0.01\) with the measured phase \(\phi _{{\rm{C}}{{\rm{H}}_3}{{\rm{I}}^ + }}^{\left( 1 \right)}\) of ~0 rad and the experimentally determined H–C–I angle of CH3I+ in the \({\tilde X^ + }\;{}^2{E_{3/2}}\) state41 (108.3 ± 0.3)° yields an equilibrium H–C–I angle of (110.0 ± 0.6)° for the I \(4d_{5/2}^{ - 1}\) core-excited state of CH3I+ (see Supplementary Note 8).
Discussion
The emergence bond softening-induced coherent vibrational motion in the present work contrasts with earlier reports, all of which observed vibrational wave packet dynamics that are attributed to R-selective depletion23,24,25. In those cases, strong-field ionization results from the removal of either a bonding (D2) or an anti-bonding electron (Br2 and I2). The change in the formal bond order upon ionization is accompanied by pronounced changes in the equilibrium bond length and vibrational frequency. For example, the equilibrium bond length45 of D2 upon ionization increases from 0.7415 to 1.0559 Å and its vibrational frequency decreases46, 47 from 2993.60 to 1577.17 cm–1. These dramatic changes in the relative displacement and curvatures of the neutral and ion potential energy curves yield an ionization potential that is strongly dependent on bond length, hence favoring the generation of vibrational wave packets via R-selective depletion. In the case of CH3I, however, strong-field ionization to the ion \({\tilde X^ + }\) state corresponds to the removal of an electron from the nonbonding iodine 5p valence orbital48. The C–I potential curves for neutral and ion species therefore run largely parallel to one another (see Supplementary Note 6), as evidenced by the subtle differences in the experimental C–I bond lengths (2.132 Å for CH3I vs. 2.126 Å for CH3I+)40, 41 and v 3 frequencies (533 cm–1 for CH3I vs. 480 cm–1 for CH3I+)34, 36, as well as the vanishingly small v 3 vibrational progression in the \({\tilde X^ + }\;{}^2{E_{3/2}}\) band of the CH3I photoelectron spectrum49. The strongly suppressed R-selective depletion channel brings to fore the contribution from bond softening. Along these lines, one would also expect the efficient launching of vibrational wave packets by bond softening in other molecules for which valence ionization results in the removal of an electron from a nonbonding orbital. Examples of such molecules include some that are commonly used in strong-field investigations, e.g., HCl4, CO2 38, H2O50, alcohols51, and organic halides19. Since bond softening corresponds to far-off-resonance Raman scattering within the photon picture23, vibrational modes that are Raman active are expected to be susceptible to bond softening.
The amplitudes of vibrational motion launched by bond softening and R-selective depletion should each exhibit a distinct dependence on the laser intensity. In general, bond softening is expected to dominate at lower intensities because of limited ionization depletion of the neutral ground state. In the case of D2, model calculations23 reveal that the relative contributions are reversed at a threshold intensity of I th~2.5 × 1014 W cm–2, with R-selective depletion dominating the response for intensities I>I th. Whether such an intensity threshold exists for CH3I is unclear, given the negligible displacement between the equilibrium C–I distances between the ground-state neutral and ion species (\(\Delta R/R = 0.003\)) and the similarity between the vibrational frequencies, and hence, the curvatures of the potentials of the two states (\(\Delta \omega /\omega = 0.1\)). In the extreme limit where both \(\Delta R\) and \(\Delta \omega /\omega\) are zero, R-selective depletion vanishes and only bond softening-induced wave packets can exist. In such cases, it is interesting to note that strong-field ionization to higher-lying electronically excited ion states could still result in vibrational motion launched by R-selective depletion. Future experiments that determine the relative contributions from bond softening and R-selective depletion as a function of laser intensity should allow one to address if an intensity threshold for CH3I exists and if electronically excited ion states participate in R-selective depletion.
The determination of equilibrium geometries of core-excited states is a non-trivial task. Experimentally, vibronic progressions that appear in static core-level photoabsorption spectra are analyzed to yield Franck–Condon factors, from which the equilibrium geometries of the N 1s −1 core-excited N2 and Si 2p −1 core-excited SiH4 have been inferred, e.g.,52, 53. However, this method is limited to core-hole states with sufficiently long lifetimes, whose narrow linewidths support clearly resolved vibronic features. For example, the natural linewidths of N 1s −1 and Si 2p −1 are 135 and 50 meV, respectively52, 53, which are comparable to or smaller than the vibrational energy spacings in the vibronic progression. This frequency-domain approach clearly cannot be extended to low-frequency vibrational modes and/or short-lived core-excited states, such as the I 4d −1 core levels probed herein (FWHM ~0.5 eV)54. Ab initio calculations of core-excited equilibrium geometries are similarly challenging due to the highly excited nature of the core-hole states55, 56, making them beyond the reach of electronic structure methods, such as multi-reference configuration interaction and complete active-space self-consistent field, that are typically employed to determine the equilibrium geometries of valence-excited states. In the present work, we show that time-domain XUV probing of vibrational wave packet dynamics furnishes the vibronic coupling involving the core-level transition and hence, the dimensionless displacement parameter, which can in turn be used to recover the equilibrium geometry of the core-excited state. While our analysis is performed only for the v 2 umbrella mode, it is important to note that the approach presented herein can be broadly generalized to the core-excited states of other molecules along their various vibrational coordinates. The ability to recover the molecular geometries of core-excited states will benefit the extensive efforts that are being pursued at X-ray free-electron lasers to investigate the ultrafast dynamics triggered by core-level excitation57, 58.
Finally, we note that previous studies of vibrational wave packet dynamics in polyatomic molecular ions created by strong-field ionization have elucidated vibrational motion only along one dimension37, 38. The observation of strong-field-induced multimode vibrational coherences, such as those reported here for CH3I+ in the \({\tilde X^ + }\;{}^2{E_{3/2}}\) state, is unprecedented and can be attributed to multiple advantages offered by our experimental approach. First, XUV absorption probing permits the spectroscopic identification of both the chemical species that are produced by strong-field ionization as well as their electronic states27. Second, large shifts in the core-level transition energies accompany small structural changes, thus enabling spectrally resolved XUV absorption spectroscopy to detect coherent vibrational amplitudes on the sub-picometer scale, as demonstrated in the present work. Third, XUV absorption spectroscopy offers exquisite time resolution, extendable to the attosecond time scale59, which translates to a large detection bandwidth for coherent vibrational motion. Fourth, the use of few-cycle pulses for strong-field ionization effectively drives wave packet dynamics involving a large manifold of vibrational modes and also provides a temporally well-defined trigger for the wave packet dynamics. The latter is crucial for establishing the initial phases of the wave packet oscillations and hence, the mechanisms for generating the vibrational coherences. Altogether, these factors point to femtosecond XUV absorption as a powerful technique for unraveling the multimode vibrational dynamics of transient molecular ions produced by intense laser–molecule interaction.
Methods
The experimental set-up (see “Supplementary Methods” section for a detailed description) employs 0.8-mJ, 5.6-fs pulses centered at 786 nm to drive high-order harmonic generation in argon gas. The resultant XUV light is transmitted through a 0.2-μm-thick aluminum foil, hence removing the residual near-infrared (NIR), before it is refocused by a gold-coated toroidal mirror onto the sample gas target. The sample target is a 3-mm-path length quasi-static gas cell that is heated to 353 K. The CH3I vapor pressure in the gas cell is 14 mbar. The transmitted XUV radiation is spectrally dispersed onto an X-ray CCD camera by a flat-field XUV grating. The strong-field-ionizing NIR pump pulse has a peak intensity of 1.9 × 1014 W cm–2 and intersects the XUV probe beam at the sample target with a crossing angle of 1°. A variable time delay between the NIR pump and XUV probe pulses is introduced by means of a computer-controlled piezo-driven delay stage positioned in the path of the NIR pump beam. The midpoint of the rise in the CH3I+ (\({\tilde X^ + }\;{}^2{E_{3/2}}\)) parent ion signal at 47.0 eV, when the instantaneous ionization rate is the highest, is used to define time-zero to a precision of 1.2 fs. The typical signal-to-noise ratio achieved after averaging over 15 scans is ~20:1.
Data availability
The data that supports the findings of this study are available from the corresponding author on request.
References
Brabec, T. & Krausz, F. Intense few-cycle laser fields: frontiers of nonlinear optics. Rev. Mod. Phys. 72, 545–591 (2000).
Popmintchev, T., Chen, M.-C., Arpin, P., Murnane, M. M. & Kapteyn, H. C. The attosecond nonlinear optics of bright coherent X-ray generation. Nat. Photon. 4, 822–832 (2010).
Milošević, D. B., Paulus, G. G., Bauer, D. & Becker, W. Above-threshold ionization by few-cycle pulses. J. Phys. B 39, R203–R262 (2006).
Meckel, M. et al. Laser-induced electron tunneling and diffraction. Science 320, 1478–1482 (2008).
Itatani, J. et al. Tomographic imaging of molecular orbitals. Nature 432, 867–871 (2004).
Vozzi, C. et al. Generalized molecular orbital tomography. Nat. Phys. 7, 822–826 (2011).
Smirnova, O. et al. High harmonic interferometry of multi-electron dynamics in molecules. Nature 460, 972–977 (2009).
Haessler, S. et al. Attosecond imaging of molecular electronic wavepackets. Nat. Phys 6, 200–206 (2010).
Boguslavskiy, A. E. et al. The multielectron ionization dynamics underlying attosecond strong-field spectroscopies. Science 335, 1336–1340 (2012).
Wörner, H. J., Bertrand, J. B., Kartashov, D. V., Corkum, P. B. & Villeneuve, D. M. Following a chemical reaction using high-harmonic interferometry. Nature 466, 604–607 (2010).
Blaga, C. I. et al. Imaging ultrafast molecular dynamics with laser-induced electron diffraction. Nature 483, 194–197 (2012).
Baker, S. et al. Probing proton dynamics in molecules on an attosecond time scale. Science 312, 424–427 (2006).
Lépine, F., Ivanov, M. Y. & Vrakking, M. J. J. Attosecond molecular dynamics: fact or fiction? Nat. Photon. 8, 195–204 (2014).
Kraus, P. M. et al. Measurement and laser control of attosecond charge migration in ionized iodoacetylene. Science 350, 790–795 (2015).
Alexander, I. K. & Lorenz, S. C. Ultrafast correlation-driven electron dynamics. J. Phys. B 47, 124002 (2014).
Sheehy, B. & DiMauro, L. F. Atomic and molecular dynamics in intense optical fields. Annu. Rev. Phys. Chem. 47, 463–494 (1996).
Posthumus, J. H. The dynamics of small molecules in intense laser fields. Rep. Prog. Phys. 67, 623–665 (2004).
Sussman, B. J., Townsend, D., Ivanov, M. Y. & Stolow, A. Dynamic stark control of photochemical processes. Science 314, 278–281 (2006).
Corrales, M. E. et al. Control of ultrafast molecular photodissociation by laser-field-induced potentials. Nat. Chem. 6, 785–790 (2014).
Fang, L. & Gibson, G. N. Investigating excited electronic states of I2 + and I2 2+ produced by strong-field ionization using vibrational wave packets. Phys. Rev. A 75, 063410 (2007).
Goll, E., Wunner, G. & Saenz, A. Formation of ground-state vibrational wave packets in intense ultrashort laser pulses. Phys. Rev. Lett. 97, 103003 (2006).
Saenz, A. Enhanced ionization of molecular hydrogen in very strong fields. Phys. Rev. A 61, 051402 (2000).
Ergler, T. et al. Quantum-phase resolved mapping of ground-state vibrational D2 wave packets via selective depletion in intense laser pulses. Phys. Rev. Lett. 97, 103004 (2006).
Fang, L. & Gibson, G. N. Strong-field induced vibrational coherence in the ground electronic state of hot I2. Phys. Rev. Lett. 100, 103003 (2008).
Hosler, E. R. & Leone, S. R. Characterization of vibrational wave packets by core-level high-harmonic transient absorption spectroscopy. Phys. Rev. A 88, 023420 (2013).
Dhar, L., Rogers, J. A. & Nelson, K. A. Time-resolved vibrational spectroscopy in the impulsive limit. Chem. Rev. 94, 157–193 (1994).
Loh, Z.-H. & Leone, S. R. Capturing ultrafast quantum dynamics with femtosecond and attosecond x-ray core-level absorption spectroscopy. J. Phys. Chem. Lett. 4, 292–302 (2013).
Attar, A. R. et al. Femtosecond x-ray spectroscopy of an electrocyclic ring-opening reaction. Science 356, 54–59 (2017).
Olney, T. N., Cooper, G. & Brion, C. E. Quantitative studies of the photoabsorption (4.5–488 eV) and photoionization (9–59.5 eV) of methyl iodide using dipole electron impact techniques. Chem. Phys. 232, 211–237 (1998).
O’Sullivan, G., McGuinness, C., Costello, J. T., Kennedy, E. T. & Weinmann, B. Trends in 4d-subshell photoabsorption along the iodine isonuclear sequence: I, I+ and I2+. Phys. Rev. A. 53, 3211–3226 (1996).
Cutler, J. N., Bancroft, G. M. & Tan, K. H. Ligand-field splittings and core-level linewidths in I 4d photoelectron spectra of iodine molecules. J. Chem. Phys. 97, 7932–7943 (1992).
Locht, R. et al. The photoionization dynamics of methyl iodide (CH3I): a joint photoelectron and mass spectrometric investigation. J. Phys. B 43, 105101 (2010).
de Nalda, R. et al. A detailed experimental and theoretical study of the femtosecond A-band photodissociation of CH3I. J. Chem. Phys. 128, 244309 (2008).
Shimanouchi, T. Tables of Molecular Vibrational Frequencies Consolidated Vol. I (National Bureau of Standards, 1972)
Duncan, J. L., Ferguson, A. M. & Mathews, S. Vibrational anharmonicity in CH3I: a joint local and normal mode study. J. Chem. Phys. 91, 783–790 (1989).
Lee, M., Bae, Y. J. & Kim, M. S. K selection in one-photon mass-analyzed threshold ionization of CH3I and CD3I to the X̃ 2 E 3∕2 state cations. J. Chem. Phys. 128, 044310 (2008).
Geißler, D., Pearson, B. J. & Weinacht, T. Wave packet driven dissociation and concerted elimination in CH2I2. J. Chem. Phys. 127, 204305 (2007).
Rudenko, A. et al. Strong-field-induced wave packet dynamics in carbon dioxide molecule. Farad. Discuss 194, 463–478 (2016).
Zeiger, H. J. et al. Theory for displacive excitation of coherent phonons. Phys. Rev. B 45, 768–778 (1992).
Matsuura, H. & Overend, J. Equilibrium structure of methyl iodide. J. Chem. Phys. 56, 5725–5727 (1972).
Bae, Y. J. & Kim, M. S. Photodissociation spectroscopy of CD3I+ generated by mass-analyzed threshold ionization for structure determination. Chemphyschem 9, 1709–1714 (2008).
Yabushita, A. & Kobayashi, T. Primary conformation change in bacteriorhodopsin on photoexcitation. Biophys. J. 96, 1447–1461 (2009).
Huang, K. & Rhys, A. Theory of light absorption and non-radiative transitions in F-centres. Proc. R. Soc. Lond. Ser. A 204, 406–423 (1950).
Lax, M. The Franck-Condon principle and its application to crystals. J. Chem. Phys. 20, 1752–1760 (1952).
Huber K. P. & Herzberg G. in NIST Chemistry WebBook, NIST Standard Reference Database Number 69 (eds Linstrom P. J. & Mallard W. G.) (National Institute of Standards and Technology) Available at http://webbook.nist.gov.
Brannon, P. J., Church, C. H. & Peters, C. W. Electric field induced spectra of molecular hydrogen, deuterium and deuterium hydride. J. Mol. Spectrosc. 27, 44–54 (1968).
Bishop, D. M. & Wetmore, R. W. Vibrational spacings for H2 +, D2 + and H2. Mol. Phys. 26, 145–157 (1973).
Walt, S. G. et al. Role of multi-electron effects in the asymmetry of strong-field ionization and fragmentation of polar molecules: the methyl halide series. J. Phys. Chem. A 119, 11772–11782 (2015).
Karlsson, L. S., Jadrny, R., Mattsson, L. H., Chau, F. T. & Siegbahn, K. Vibrational and vibronic structure in the valence electron spectra of CH3X molecules (X=F, Cl, Br, I, OH). Phys. Scripta 16, 225–234 (1977).
Farrell, J. P. et al. Strong field ionization to multiple electronic states in water. Phys. Rev. Lett. 107, 083001 (2011).
Ando, T. et al. Wave packet bifurcation in ultrafast hydrogen migration in CH3OH+ by pump-probe coincidence momentum imaging with few-cycle laser pulses. Chem. Phys. Lett. 624, 78–82 (2015).
Chen, C. T., Ma, Y. & Sette, F. K-shell photoabsorption of the N2 molecule. Phys. Rev. A 40, 6737–6740 (1989).
Püttner, R., Domke, M., Lentz, D. & Kaindl, G. Si 2p photoabsorption in SiH4 and SiD4: molecular distortion in core-excited silane. Phys. Rev. A 56, 1228–1239 (1997).
O’Sullivan, G. The absorption spectrum of CH3I in the extreme VUV. J. Phys. B 15, L327–L330 (1982).
Norman, P. & Ågren, H. Geometry optimization of core electron excited molecules. J. Mol. Struc. 401, 107–115 (1997).
Trofimov, A. B., Gromov, E. V., Moskovskaya, T. E. & Schirmer, J. Theoretical evidence for a bound doubly-excited 1B2 (C 1s, n→π*2) state in H2CO below the C 1s ionization threshold. J. Chem. Phys. 113, 6716–6723 (2000).
Erk, B. et al. Imaging charge transfer in iodomethane upon x-ray photoabsorption. Science 345, 288–291 (2014).
McFarland, B. K. et al. Ultrafast x-ray auger probing of photoexcited molecular dynamics. Nat. Commun. 5, 4235 (2014).
Goulielmakis, E. et al. Real-time observation of valence electron motion. Nature 466, 739–743 (2010).
Acknowledgements
This work is supported by a NTU start-up grant, the A*Star Science and Engineering Research Council Public Sector Funding (122-PSF-0011 and 122 360 0008), the Ministry of Education Academic Research Fund (MOE2014-T2-2-052), and the award of a Nanyang Assistant Professorship to Z.-H.L. M.Y. acknowledges the financial support from National Natural Science Foundation of China (NSFC, Project No. 21373266). We are grateful to K. Yamanouchi, T. Kobayashi, S.L. Chin, and D. Mathur for useful discussions.
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Z.W. and J.L. performed the experiment. M.H.J., Z.-H.L., Y.Z., F.S., and M.Y. performed the theoretical calculations. J.L., Z.W., L.W., S.T.S., and Z.-H.L. designed and constructed the experimental set-up. Z.W. and Z.-H.L. wrote the manuscript, with input from all the authors.
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Wei, Z., Li, J., Wang, L. et al. Elucidating the origins of multimode vibrational coherences of polyatomic molecules induced by intense laser fields. Nat Commun 8, 735 (2017). https://doi.org/10.1038/s41467-017-00848-2
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DOI: https://doi.org/10.1038/s41467-017-00848-2
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