Transduction of single nanomechanical pillar resonators by scattering of surface acoustic waves

TL;DR

This paper introduces a novel, material-independent electromechanical transduction method for single nanomechanical pillar resonators using surface acoustic waves, enabling efficient detection of freestanding nanostructures.

Contribution

The authors present a general SAW-based transduction technique for nanomechanical pillars, overcoming fabrication and material constraints of previous methods.

Findings

Successful transduction of freestanding platinum-carbon pillars

Operates in first-order bending and compression modes

Independent of pillar material and geometry

Abstract

One of the challenges of nanoelectromechanical systems (NEMS) is the effective transduction of the tiny resonators. Vertical structures, such as nanomechanical pillar resonators, which are exploited in a wide range of fields, such as optomechanics, acoustic metamaterials, and nanomechanical sensing, are particularly challenging to transduce. Existing electromechanical transduction methods are ill-suited as they complicate the pillars' fabrication process, put constraints on the pillars' material, and do not enable a transduction of freestanding pillars. Here, we present an electromechanical transduction method for single nanomechanical pillar resonators based on surface acoustic waves (SAWs). We demonstrate the transduction of freestanding nanomechanical platinum-carbon pillars in the first-order bending and compression mode. Since the principle of the transduction method is based on resonant scattering of a SAW by a nanomechanical resonator, our transduction method is independent of the pillar's material and not limited to pillar-shaped geometries. It represents a general method to transduce vertical mechanical resonators with nanoscale lateral dimensions.