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Controlling the thermal conductivity of multilayer graphene by strain

Kaito Nakagawa, Kazuo Satoh, Shuichi Murakami, Kuniharu Takei, Seiji Akita, Takayuki Arie

2021Scientific Reports25 citationsDOIOpen Access PDF

Abstract

Straintronics is a new concept to enhance electronic device performances by strain for next-generation information sensors and energy-saving technologies. The lattice deformation in graphene can modulate the thermal conductivity because phonons are the main heat carriers. However, the device fabrication process affects graphene's heat transport properties due to its high stretchability. This study experimentally investigates the change in the thermal conductivity when biaxial tensile strain is applied to graphene. To eliminate non-strain factors, two mechanisms are considered: pressure-induced and electrostatic attraction-induced strain. Raman spectroscopy and atomic force microscopy precisely estimate the strain. The thermal conductivity of graphene decreases by approximately 70% with a strain of only 0.1%. Such thermal conductivity controllability paves the way for applying graphene as high-efficiency thermal switches and diodes in future thermal management devices.

Topics & Concepts

GrapheneThermal conductivityMaterials scienceRaman spectroscopyPhononStrain (injury)Strain engineeringOptoelectronicsNanotechnologyComposite materialCondensed matter physicsOpticsInternal medicineMedicineSiliconPhysicsGraphene research and applicationsThermal properties of materialsThermal Radiation and Cooling Technologies
Controlling the thermal conductivity of multilayer graphene by strain | Litcius