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Printable G‐Putty for Frequency‐ and Rate‐Independent, High‐Performance Strain Sensors

Daniel P. O’Driscoll, Sean McMahon, James Garcia, Sonia Biccai, Cian Gabbett, Adam G. Kelly, Sebastian Barwich, Matthias Moebius, Conor S. Boland, Jonathan N. Coleman

2021Small27 citationsDOI

Abstract

Abstract While nanocomposite electromechanical sensors are expected to display reasonable conductivity and high sensitivity, little consideration is given to eliminating hysteresis and strain rate/frequency dependence from their response. For example, while G‐putty, a composite of graphene and polysiloxane, has very high electromechanical sensitivity, its extreme viscoelasticity renders it completely unsuitable for real sensors due to hysteretic and rate‐/frequency‐dependent effects. Here it is shown that G‐putty can be converted to an ink and printed into patterned thin films on elastic substrates. A partial graphene‐polymer phase segregation during printing increases the thin‐film conductivity by ×10 6 compared to bulk, while the mechanical effects of the substrate largely suppress hysteresis and completely remove strain rate and frequency dependence. This allows the fabrication of practical, high‐gauge‐factor, wearable sensors for pulse measurements as well as patterned sensors for low‐signal vibration sensing.

Topics & Concepts

Materials scienceGauge factorHysteresisViscoelasticityComposite materialGrapheneSensitivity (control systems)FabricationSubstrate (aquarium)ConductivityComposite numberThin filmOptoelectronicsNanotechnologyElectronic engineeringCondensed matter physicsAlternative medicinePathologyGeologyPhysical chemistryMedicinePhysicsOceanographyEngineeringChemistryAdvanced Sensor and Energy Harvesting MaterialsDielectric materials and actuatorsConducting polymers and applications
Printable G‐Putty for Frequency‐ and Rate‐Independent, High‐Performance Strain Sensors | Litcius