Self-Assembled Cellulose Nanocrystal-MXene Hybrid Film for Acceleration Sensing.
Omer Shoseyov, Daniel Voignac, Shylee Belsey, Danielle Sviri, Shira Yochelis, Maxim Sokol, Oded Shoseyov, Yossi Paltiel
Abstract
Open AccessAdvances in robotics and micromechanical systems demand miniaturized, low-cost electromechanical sensors. Conventional micro-electromechanical systems (MEMS) rely on complex, expensive top-down fabrication, limiting scalability. Here, we introduce a bottom-up approach for fabricating a flexible acceleration sensor using cellulose nanocrystal (CNC) films combined with conductive 2D MXene nanosheets. The self-assembled hybrid film exhibits sensitivity to acceleration, enabling precise three-axis motion detection. Functioning like a flexible field-effect transistor, the device uses acceleration-induced film deformation to generate charge separation in the chiral piezo films, producing a gating effect with measurable voltage shifts proportional to applied acceleration. This piezoelectric response allows real-time accurate motion tracking. Unlike conventional sensors, the device exhibits nonlinear behavior and is insensitive to the motion direction. Our approach offers a cost-effective solution for applications requiring dynamic motion detection and precise acceleration quantification, while simplifying fabrication and expanding the possibilities for next-generation nano and micro sensing technologies.