Ring-Closing Reaction in Diarylethene Captured by Femtosecond Electron Crystallography

Jean-Ruel, Hubert; Gao, Meng; Kochman, Marian; Lü, Cheng; Liu, Lai Chung; Cooney, Ryan R.; Morrison, Carole A.; Miller, R. J. Dwayne

doi:10.1021/jp409245h

Cited by 82 publications

(65 citation statements)

References 52 publications

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“…We attribute this to some additional noise of our single-electron detection scheme 44 . Nevertheless, for many of the spots, the signal-to-noise ratio achieved here would allow seeing changes of a few percent in Bragg spot intensities, comparable to conventional multi-electron approaches 6,10,64 . There is no significant difference in noise between the one-electron and the ten-electron measurement.…”

Section: Signal-to-noisementioning

confidence: 77%

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Femtosecond single-electron diffraction

Lahme

Kealhofer

Krausz

et al. 2014

Structural Dynamics

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Ultrafast electron diffraction allows the tracking of atomic motion in real time, but space charge effects within dense electron packets are a problem for temporal resolution. Here, we report on time-resolved pump-probe diffraction using femtosecond single-electron pulses that are free from intra-pulse Coulomb interactions over the entire trajectory from the source to the detector. Sufficient average electron current is achieved at repetition rates of hundreds of kHz. Thermal load on the sample is avoided by minimizing the pump-probe area and by maximizing heat diffusion. Time-resolved diffraction from fibrous graphite polycrystals reveals coherent acoustic phonons in a nanometer-thick grain ensemble with a signal-to-noise level comparable to conventional multi-electron experiments. These results demonstrate the feasibility of pump-probe diffraction in the single-electron regime, where simulations indicate compressibility of the pulses down to few-femtosecond and attosecond duration.

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Section: Signal-to-noisementioning

confidence: 77%

“…In practice, however, the repetition rate is limited by the thermal load imposed by the excitation process 3 to a few hundreds of kHz. We note that single-electron diffraction at 1–10 kHz used in the majority of UED experiments 6,41,42 would require net exposure times on the order of weeks.…”

Section: Introductionmentioning

confidence: 99%

Femtosecond single-electron diffraction

Lahme

Kealhofer

Krausz

et al. 2014

Structural Dynamics

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“…Ultrafast electron diffraction (UED) is a highly successful technique for structural dynamics investigation of phase transitions, electron-phonon coupling, and chemical reactions. [1][2][3][4][5][6][7][8][9] Metal photocathodes are currently the most commonly employed electron sources due to their robustness, ultrafast temporal response, and compatibility with high electric fields. They provide sub-picosecond electron pulses with coherence lengths up to a few nanometers.…”

mentioning

confidence: 99%

Optical fiber-based photocathode

Casandruc

Bücker

Kassier

et al. 2016

Applied Physics Letters

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“…UED has been applied to a variety of crystalline samples and provided detailed information about photoinduced structural processes. However, its application to labile organic materials has only been recently realized 3,4 . Source brightness has been one of the most challenging tasks to extend UED to effectively monitor molecular motion in labile organic systems.…”

Section: Introductionmentioning

confidence: 99%

Ultrabright femtosecond electron sources: perspectives and challenges towards the study of structural dynamics in labile systems

Gao

Jean-Ruel

Lü

et al. 2014

Ultrafast Nonlinear Imaging and Spectroscopy II

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The advances made in femtosecond electron sources over the last thirty years have been remarkable. In particular, the development of ultrabright femtosecond electron sources has made possible the observation of molecular motion in labile organic materials and it is paving the way towards the study of complex protein systems. The principle of radio frequency (RF) rebunching cavities for the compression of ultrabright electron pulses is presented, alongside with a recent demonstration of its capabilities in capturing the relevant photoinduced dynamics in weakly scattering organic systems. Organic and biological systems can easily decompose or lose crystallinity as a consequence of cumulative heating effects or the formation of side reaction photoproducts. Hence, source brightness plays a crucial role in achieving sufficient signal-to-noise ratio before degradation effects become noticeable on the structural properties of the material. The current brightness of electron sources in addition to the high scattering cross section of keV-MeV electrons have made femtosecond electron diffraction a powerful tool for the study of materials composed by low-Z elements

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Ring-Closing Reaction in Diarylethene Captured by Femtosecond Electron Crystallography

Cited by 82 publications

References 52 publications

Femtosecond single-electron diffraction

Femtosecond single-electron diffraction

Optical fiber-based photocathode

Ultrabright femtosecond electron sources: perspectives and challenges towards the study of structural dynamics in labile systems

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