Inkjet Printed Large‐Area Flexible Few‐Layer Graphene Thermoelectrics |
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Authors: | Taneli Juntunen Henri Jussila Mikko Ruoho Shouhu Liu Guohua Hu Tom Albrow‐Owen Leonard W T Ng Richard C T Howe Tawfique Hasan Zhipei Sun Ilkka Tittonen |
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Affiliation: | 1. Department of Electronics and Nanoengineering, Aalto University, Aalto, Finland;2. Cambridge Graphene Centre, University of Cambridge, Cambridge, UK;3. QTF Centre of Excellence, Department of Applied Physics, Aalto University, Aalto, Finland |
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Abstract: | Graphene‐based organic nanocomposites have ascended as promising candidates for thermoelectric energy conversion. In order to adopt existing scalable printing methods for developing thermostable graphene‐based thermoelectric devices, optimization of both the material ink and the thermoelectric properties of the resulting films are required. Here, inkjet‐printed large‐area flexible graphene thin films with outstanding thermoelectric properties are reported. The thermal and electronic transport properties of the films reveal the so‐called phonon‐glass electron‐crystal character (i.e., electrical transport behavior akin to that of few‐layer graphene flakes with quenched thermal transport arising from the disordered nanoporous structure). As a result, the all‐graphene films show a room‐temperature thermoelectric power factor of 18.7 µW m?1 K?2, representing over a threefold improvement to previous solution‐processed all‐graphene structures. The demonstration of inkjet‐printed thermoelectric devices underscores the potential for future flexible, scalable, and low‐cost thermoelectric applications, such as harvesting energy from body heat in wearable applications. |
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Keywords: | graphene inkjet printing large‐area thermoelectrics |
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