Impulsively Excited Surface Phononic Crystals: A Route Toward Novel Sensing Schemes

Author

Nardi, Damiano ; Travagliati, Marco ; Murnane, Margaret M. ; Kapteyn, Henry C. ; Ferrini, Gabriele ; Giannetti, Claudio ; Banfi, Francesco

Author_Institution

Dept. of Phys., Univ. of Colorado, Boulder, CO, USA

Volume

15

Issue

9

fYear

2015

Firstpage

5142

Lastpage

5150

Abstract

The application of all-optical time resolved techniques to nanostructured surface phononic crystals (SPCs) enables the generation and detection of hypersonic frequency surface acoustic waves up to 50 GHz, with great potential for innovations in nanometrology and sensing applications. In this paper, we review the advances in this field in both experiments and theory, focusing on the progress in nondestructive nanometrology of ultrathin films, on the potential for a dramatic increase in the sensitivity of mass sensors due to enhanced acoustic wave surface confinement, and on the evolution of this approach to include polymer-coated SPCs for soft material and gas sensing applications. A survey of the enabling innovative optical technologies involved is presented.

Keywords

gas sensors; mass measurement; optical sensors; phononic crystals; surface acoustic wave sensors; acoustic wave surface confinement; all-optical time resolved techniques; gas sensing applications; hypersonic frequency surface acoustic waves; impulsively excited surface phononic crystals; mass sensors; nanostructured surface phononic crystals; nondestructive nanometrology; polymer-coated surface phononic crystals; soft material; ultrathin films; Gratings; Optical surface waves; Polymers; Sensors; Substrates; Surface acoustic waves; Acoustic sensing; nanomechanics; phononic crystals; surface acoustic waves; ultrafast optics;

fLanguage

English

Journal_Title

Sensors Journal, IEEE

Publisher

ieee

ISSN

1530-437X

Type

jour

DOI

10.1109/JSEN.2015.2436881

Filename

7111216