Frenkel-Poole Mechanism Unveils Black Diamond as Quasi-Epsilon-Near-Zero Surface.

Andrea Orsini,Sara Pettinato,Alessandro Bellucci,Stefano Orlando,Daniele Barettin,Matteo Mastellone,Eleonora Bolli,Stefano Salvatori,Valerio Serpente,Daniele Maria Trucchi,Marco Girolami,Veronica Valentini,Riccardo Polini,Maria Cristina Rossi

doi:10.3390/nano13020240

Frenkel-Poole Mechanism Unveils Black Diamond as Quasi-Epsilon-Near-Zero Surface.

Andrea Orsini, Sara Pettinato + Show 12 more

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https://doi.org/10.3390/nano13020240

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Journal: Nanomaterials	Publication Date: Jan 5, 2023
Citations: 1	License type: CC BY 4.0

Affiliation: University Niccolò Cusano, Institute of Structure of Matter, University of Rome Tor Vergata

#Black Diamond #High Electric Field Condition + Show 8 more

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Abstract

A recent innovation in diamond technology has been the development of the "black diamond" (BD), a material with very high optical absorption generated by processing the diamond surface with a femtosecond laser. In this work, we investigate the optical behavior of the BD samples to prove a near to zero dielectric permittivity in the high electric field condition, where the Frenkel-Poole (FP) effect takes place. Zero-epsilon materials (ENZ), which represent a singularity in optical materials, are expected to lead to remarkable developments in the fields of integrated photonic devices and optical interconnections. Such a result opens the route to the development of BD-based, novel, functional photonic devices.

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