Litcius/Paper detail

Two-Dimensional Mechano-thermoelectric Heterojunctions for Self-Powered Strain Sensors

Yingyu Wang, Ding‐Rui Chen, Jen-Kai Wu, Tian-Hsin Wang, Chiashain Chuang, S. Y. Huang, Wen‐Pin Hsieh, Mario Hofmann, Yuan-Huei Chang, Ya‐Ping Hsieh

2021Nano Letters24 citationsDOI

Abstract

We here demonstrate the multifunctional properties of atomically thin heterojunctions that are enabled by their strong interfacial interactions and their application toward self-powered sensors with unprecedented performance. Bonding between tin diselenide and graphene produces thermoelectric and mechanoelectric properties beyond the ability of either component. A record-breaking ZT of 2.43 originated from the synergistic combination of graphene’s high carrier conductivity and SnSe2-mediated thermal conductivity lowering. Moreover, spatially varying interaction at the SnSe2/graphene interface produces stress localization that results in a novel 2D-crack-assisted strain sensing mechanism whose sensitivity (GF = 450) is superior to all other 2D materials. Finally, a graphene-assisted growth process permits the formation of high-quality heterojunctions directly on polymeric substrates for flexible and transparent sensors that achieve self-powered strain sensing from a small temperature gradient. Our work enhances the fundamental understanding of multifunctionality at the atomic scale and provides a route toward structural health monitoring through ubiquitous and smart devices.

Topics & Concepts

HeterojunctionGrapheneMaterials scienceThermoelectric effectNanotechnologyOptoelectronicsConductivitySemiconductorStress (linguistics)Strain engineeringSiliconChemistryThermodynamicsPhysicsPhysical chemistryPhilosophyLinguisticsAdvanced Thermoelectric Materials and DevicesAdvanced Sensor and Energy Harvesting MaterialsThermal properties of materials