Recoil-induced ultrafast molecular rotation probed by dynamical rotational Doppler effect

Denis Céolin; Ji-Cai Liu; Vinícius Vaz da Cruz; Hans Ågren; Loïc Journel; Renaud Guillemin; Tatiana Marchenko; Rajesh K. Kushawaha; Maria Novella Piancastelli; Ralph Püttner; Marc Simon; Faris Gel’mukhanov

doi:10.1073/pnas.1807812116

New Research In

Edited by Philippe Wernet, Helmholtz-Zentrum Berlin für Materialien und Energie, Berlin, Germany, and accepted by Editorial Board Member Richard Eisenberg December 18, 2018 (received for review May 11, 2018)

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Significance

Ionization of molecules by hard X-ray photons induces ultrafast rotation up to an effective rotational temperature of about 10,000 K due to the recoil caused by emission of a fast photoelectron. The goal to monitor the recoil-induced rotational motion and finally control its dynamics is achieved by recording high-resolution Auger spectra of the C1s core-ionized carbon monoxide molecule. The time-delayed Auger electron emission offers a unique opportunity to probe the dynamics of ultrafast molecular rotation, since we show that a significant change of the molecular orientation occurs during Auger decay. We exploit the fact that the rotational period is comparable with the core-hole lifetime. We manipulate this dynamics by changing the rotational speed using X-ray photons of different energies.

Abstract

Observing and controlling molecular motion and in particular rotation are fundamental topics in physics and chemistry. To initiate ultrafast rotation, one needs a way to transfer a large angular momentum to the molecule. As a showcase, this was performed by hard X-ray C1s ionization of carbon monoxide accompanied by spinning up the molecule via the recoil “kick” of the emitted fast photoelectron. To visualize this molecular motion, we use the dynamical rotational Doppler effect and an X-ray “pump-probe” device offered by nature itself: the recoil-induced ultrafast rotation is probed by subsequent Auger electron emission. The time information in our experiment originates from the natural delay between the C1s photoionization initiating the rotation and the ejection of the Auger electron. From a more general point of view, time-resolved measurements can be performed in two ways: either to vary the “delay” time as in conventional time-resolved pump-probe spectroscopy and use the dynamics given by the system, or to keep constant delay time and manipulate the dynamics. Since in our experiment we cannot change the delay time given by the core-hole lifetime τ, we use the second option and control the rotational speed by changing the kinetic energy of the photoelectron. The recoil-induced rotational dynamics controlled in such a way is observed as a photon energy-dependent asymmetry of the Auger line shape, in full agreement with theory. This asymmetry is explained by a significant change of the molecular orientation during the core-hole lifetime, which is comparable with the rotational period.

Footnotes

↵¹To whom correspondence may be addressed. Email: denis.ceolin{at}synchrotron-soleil.fr, jicailiu{at}ncepu.edu.cn, or puettner{at}zedat.fu-berlin.de.

Author contributions: D.C., M.N.P., R.P., and M.S. designed research; D.C., J.-C.L., V.V.d.C., L.J., R.G., T.M., R.K.K., M.N.P., R.P., M.S., and F.G. performed research; D.C., J.-C.L., R.P., and F.G. analyzed data; and D.C., J.-C.L., H.Å., and F.G. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission. P.W. is a guest editor invited by the Editorial Board.
Data deposition: The datasets generated and/or analyzed during this study are available from the LCPMR laboratory repository, https://lcpmr.cnrs.fr/content/relaxation-de-molecules-excitees-en-couche-interne/downloads.
See Commentary on page 4772.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1807812116/-/DCSupplemental.

Published under the PNAS license.

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