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Issue 5, 2019
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Ultrafast rotational motions of supported nanoclusters probed by electron diffraction

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Abstract

In crystals, microscopic energy flow is governed by electronic and vibrational excitations. In nanoscale materials, however, translations and rotations of entire nanoparticles represent additional fundamental excitations. The observation of such motions is elusive as most ultrafast techniques are insensitive to motions of the phonons’ frame of reference. Here, we study heterostructures of size-selected Au nanoclusters with partial (111) orientation on few-layer graphite with femtosecond electron diffraction. We demonstrate that ultrafast, constrained rotations of nanoclusters, so-called librations, in photo-induced non-equilibrium conditions can be observed separately from vibrational structural dynamics. Molecular dynamics and electron diffraction simulations provide quantitative understanding on librations-induced deviations from the conventional temperature dependence of diffraction patterns. We find that nanocluster librations with a period of ∼20 picoseconds are triggered quasi-impulsively by graphene flexural motions. These ultrafast structural dynamics modulate the Au/C interface and hence are expected to play a key role in energy- and mass-transport at the nanoscale.

Graphical abstract: Ultrafast rotational motions of supported nanoclusters probed by electron diffraction

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Supplementary files

Article information


Submitted
15 Jan 2019
Accepted
08 May 2019
First published
09 May 2019

This article is Open Access

Nanoscale Horiz., 2019,4, 1164-1173
Article type
Communication

Ultrafast rotational motions of supported nanoclusters probed by electron diffraction

T. Vasileiadis, E. N. Skountzos, D. Foster, S. P. Coleman, D. Zahn, F. Krečinić, V. G. Mavrantzas, R. E. Palmer and R. Ernstorfer, Nanoscale Horiz., 2019, 4, 1164
DOI: 10.1039/C9NH00031C

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