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Quantifying the Piezoresistive Mechanism in High-Performance Printed Graphene Strain Sensors

Eoin Caffrey, James Garcia, Domhnall O’Suilleabhain, Cian Gabbett, Tian Carey, Jonathan N. Coleman

2022ACS Applied Materials & Interfaces53 citationsDOIOpen Access PDF

Abstract

), they often perform poorly in the other areas. Recently, evidence has been growing that printed, polymer-free networks of nanoparticles, such as graphene nanosheets, display very good all-round sensing performance, although the details of the sensing mechanism are poorly understood. Here, we perform a detailed characterization of the thickness dependence of piezoresistive sensors based on printed networks of graphene nanosheets. We find both conductivity and gauge factor to display percolative behavior at low network thickness but bulk-like behavior for networks above ∼100 nm thick. We use percolation theory to derive an equation for gauge factor as a function of network thickness, which well-describes the observed thickness dependence, including the divergence in gauge factor as the percolation threshold is approached. Our analysis shows that the dominant contributor to the sensor performance is not the effect of strain on internanosheet junctions but the strain-induced modification of the network structure. Finally, we find these networks display excellent cyclability, hysteresis, and frequency/strain-rate dependence as well as gauge factors as high as 350.

Topics & Concepts

Materials sciencePiezoresistive effectGrapheneMechanism (biology)NanotechnologyStrain (injury)Composite materialOptoelectronicsPhilosophyMedicineEpistemologyInternal medicineAdvanced Sensor and Energy Harvesting MaterialsGas Sensing Nanomaterials and SensorsAdditive Manufacturing and 3D Printing Technologies
Quantifying the Piezoresistive Mechanism in High-Performance Printed Graphene Strain Sensors | Litcius