Parallel measurements of vibrational modes in a few-layer graphene nanomechanical resonator using software-defined radio dongles

TL;DR

This paper demonstrates using inexpensive software-defined radio dongles combined with MATLAB and GNU Radio to measure and analyze vibrational modes in a graphene nanomechanical resonator, offering a cost-effective alternative to traditional instruments.

Contribution

It introduces a novel application of SDR dongles for parallel vibrational mode measurements in nanomechanical resonators, integrating optical detection and software processing.

Findings

Successfully measured the first vibrational mode dynamics.

Achieved parallel detection of multiple vibrational modes.

Demonstrated voice demodulation from resonator vibrations.

Abstract

Software-defined radio dongles are small and inexpensive receivers well known to amateur radio enthusiasts. When connected to an antenna, they enable monitoring of a wide range of the radio spectrum by conditioning the input signal and transferring a downconverted version of it to a personal computer for software processing. Here, we employ a composite of two such dongles, interfaced with codes written in MATLAB and GNU Radio, as a measuring instrument to study the flexural vibrations of a few-layer graphene nanomechanical resonator. Instead of an antenna, we connect the dongles to the split output of a photodetector used to detect vibrations optically. We first perform a quantitative analysis of the dynamics of the first vibrational mode. We then measure the response of the first two vibrational modes in parallel. To illustrate our technique, we detect changes in the vibrational amplitude of both modes induced by periodic strain modulation with a delay of $\approx1$ ms between measurements. Last, we show that our software-based instrument can be employed to demodulate human voice encoded in the vibrations of our resonator. For parallel measurements of several frequency channels, and provided that the input signal is not too weak, our composite system may offer an alternative to the use of multiple lock-in amplifiers or multiple spectrum analyzers, with the distinct advantage of being cost-effective per frequency channel.