posted on 2018-07-11, 00:00authored byThomas Vasileiadis, Lutz Waldecker, Dawn Foster, Alessandra Da Silva, Daniela Zahn, Roman Bertoni, Richard E. Palmer, Ralph Ernstorfer
We
study the ultrafast structural dynamics, in response to electronic
excitations, in heterostructures composed of size-selected Au nanoclusters
on thin-film substrates with the use of femtosecond electron diffraction.
Various forms of atomic motion, such as thermal vibrations, thermal
expansion, and lattice disordering, manifest as distinct and quantifiable
reciprocal-space observables. In photoexcited supported nanoclusters,
thermal equilibration proceeds through intrinsic heat flow between
their electrons and their lattice and extrinsic heat flow between
the nanoclusters and their substrate. For an in-depth understanding
of this process, we have extended the two-temperature model to the
case of 0D/2D heterostructures and used it to describe energy flow
among the various subsystems, to quantify interfacial coupling constants
and to elucidate the role of the optical and thermal substrate properties.
When lattice heating of Au nanoclusters is dominated by intrinsic
heat flow, a reversible disordering of atomic positions occurs, which
is absent when heat is injected as hot substrate phonons. The present
analysis indicates that hot electrons can distort the lattice of nanoclusters,
even if the lattice temperature is below the equilibrium threshold
for surface premelting. Based on simple considerations, the effect
is interpreted as activation of surface diffusion due to modifications
of the potential energy surface at high electronic temperatures. We
discuss the implications of such a process in structural changes during
surface chemical reactions.