Cavity-enhanced photo-thermoelectric response in graphene under cyclotron resonance

Citations Over Time

Abstract

We investigated the photo-thermoelectric response of Landau-quantized graphene in an infrared optical cavity structure. High-quality graphene/h-BN heterostructure was fabricated on a TiO2/Au optical cavity. We observed a large enhancement of the photo-thermoelectric voltage when the energy of the inter-Landau-level optical absorption, so-called cyclotron resonance, was coincident with that of the cavity mode. This is due to cavity-enhanced cyclotron resonance absorption of mid-infrared light. A maximum photovoltage responsivity of ∼107 V/W was obtained at a wavelength of 9.27 μm under a magnetic field as low as ∼1 Tesla. The obtained responsivity was significantly higher than that of conventional graphene devices. Our results provide an efficient photo-thermoelectric conversion scheme that utilizes Landau-quantized graphene and an optical cavity.

Related Papers

• → The effect of substrates on the Raman spectrum of graphene: Graphene- on-sapphire and graphene-on-glass(2007)250 cited
• → Orthotropic friction at the edges and interior of graphene and graphene fluoride and frictional anisotropy of graphene at the nanoscale(2021)1 cited
• A natural advantage? Using mined graphite to make graphene(2013)
• Synthesis and Characterisation of Graphene Single Sheets(2012)
• Unique synthesis of graphene-based materials for clean energy and biological sensing applications(2012)