Thermo-mechanical behavior of surface acoustic waves in ordered arrays
  of nanodisks studied by near infrared pump-probe diffraction experiments

A. Okhotin; B. Auld; B. Revaz; C. Giannetti; E. Bontempi; E. Hecht; F. Banfi; F. Cilento; F. J. H. Stocker; F. Parmigiani; G. Ferrini; G. Grosso; G. Oliviero; L. Bonacina; L. E. Depero; M. Montagnese; M. Roukes; P. Vavassori; S. Anisimov; S. Maccalli; V. Metlushko

research

Thermo-mechanical behavior of surface acoustic waves in ordered arrays of nanodisks studied by near infrared pump-probe diffraction experiments

Authors: A. Okhotin
B. Auld
B. Revaz
C. Giannetti
E. Bontempi
E. Hecht
F. Banfi
F. Cilento
F. J. H. Stocker
F. Parmigiani
G. Ferrini
G. Grosso
G. Oliviero
L. Bonacina
L. E. Depero
M. Montagnese
M. Roukes
P. Vavassori
S. Anisimov
S. Maccalli
V. Metlushko
Publication date: 1 January 2007
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The ultrafast thermal and mechanical dynamics of a two-dimensional lattice of metallic nano-disks has been studied by near infrared pump-probe diffraction measurements, over a temporal range spanning from 100 fs to several nanoseconds. The experiments demonstrate that, in these systems, a two-dimensional surface acoustic wave (2DSAW), with a wavevector given by the reciprocal periodicity of the array, can be excited by ~120 fs Ti:sapphire laser pulses. In order to clarify the interaction between the nanodisks and the substrate, numerical calculations of the elastic eigenmodes and simulations of the thermodynamics of the system are developed through finite-element analysis. At this light, we unambiguously show that the observed 2DSAW velocity shift originates from the mechanical interaction between the 2DSAWs and the nano-disks, while the correlated 2DSAW damping is due to the energy radiation into the substrate.Comment: 13 pages, 10 figure