Super-Elastic Graphene Ripples for Flexible Strain Sensors

Citations Over TimeTop 1% of 2011 papers

Abstract

In this study, we report a buckling approach for graphene and graphene ribbons on stretchable elastomeric substrates. Stretched polydimethylsiloxane (PDMS) films with different prestrains were used to receive the transferred graphene, and nanoscale periodical buckling of graphene was spontaneously formed after strain release. The morphology and periodicity of the as-formed graphene ripples are dependent strongly on their original shapes and substrates' prestrains. Regular periodicity of the ripples preferred to form for narrow graphene ribbons, and both the amplitude and periodicity are reduced with the increase of prestrain on PDMS. The graphene ripples have the ability to afford large strain deformation, thus making it ideal for flexible electronic applications. It was demonstrated that both graphene ribbon and nanographene film ripples could be used for strain sensors, and their resistance changes upon different strains were studied. This simple and controllable process of buckled graphene provides a feasible fabrication for graphene flexible electronic devices and strain sensors due to its novel mechanical and electrical properties.

Related Papers

• → Replication and Compression of Surface Structures with Polydimethylsiloxane Elastomer(1999)110 cited
• → Highly Transparent, Stretchable, and Conducting Ionoelastomers Based on Poly(ionic liquid)s(2021)74 cited
• → Elastomeric substrates with embedded stiff platforms for stretchable electronics(2013)114 cited
• → Post-buckling analysis for the precisely controlled buckling of thin film encapsulated by elastomeric substrates(2007)81 cited
• → Stretchable, Bifacial Si-Organic Hybrid Solar Cells by Vertical Array of Si Micropillars Embedded into Elastomeric Substrates(2018)16 cited