Molecule-based microelectromechanical sensors

TL;DR

This paper introduces a novel hybrid microelectromechanical sensor functionalized with switchable magnetic molecules, capable of sensing light and heat, and functioning as a nonvolatile memory device, advancing molecular electronics and sensor technology.

Contribution

The work presents the first integration of switchable magnetic molecules with polymer MEMS resonators, enabling environmental sensing and data storage functionalities.

Findings

Device's resonance frequency changes with magnetic state switching.

Sensor can detect light and thermal stimuli.

Device operates as a nonvolatile memory.

Abstract

Incorporating functional molecules into sensor devices is an emerging field in molecular electronics that aims at exploiting the sensitivity of different molecules to their environment and turning it into an electrical signal. Among the emergent sensors, microelectromechanical systems are promising for their extreme sensitivity to mechanical events. However, in order to bring new functions to these devices, the functionalization of their surface with multifunctional molecules is required. Herein, we present original hybrid devices made of an integrated polymer microelectromechanical resonator functionalized with switchable magnetic molecules. The change of their mechanical properties and geometry induced by the switching of their magnetic state at a molecular level alters the device dynamical behavior, resulting in a change of the resonance frequency. We demonstrate that the device can be operated to sense light or thermal excitation. Moreover, thanks to the collective interaction of the switchable molecules, the device behaves as a nonvolatile memory. Our results open up broad prospects of new flexible photo and thermoactive hybrid devices for molecule based data storage and sensors.