Enhanced broadband light absorption by WSe2 mono layers via surface plasmon structures

During the last decade, electronic and photonic properties of two-dimensional materials like graphene and transition metal dicalcogenides, have attracted the attention of research in nanophotonics and optoelectronics. Unlike graphene with zero energy gap, transition metal dicalcogenides like WSe2, i...

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Bibliographic Details
Published in:Iranian Journal of Physics Research Vol. 23; no. 2; pp. 367 - 377
Main Authors: Zahra Sadegh Tabrizi, Mehdi khazaei nezhad
Format: Journal Article
Language:English
Published: Isfahan University of Technology 01-09-2023
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Summary:During the last decade, electronic and photonic properties of two-dimensional materials like graphene and transition metal dicalcogenides, have attracted the attention of research in nanophotonics and optoelectronics. Unlike graphene with zero energy gap, transition metal dicalcogenides like WSe2, in their bulk state, have extreme and indirect energy gaps. Moreover, direct bandgaps have approached in visible and infrared regime by reducing the thickness of them to one layer. However, because of their inherent small atomic thickness, these materials face a severe challenge in interaction of light and matter that leads to weak absorption and emission of light. For instance, monolayers of WSe₂ with a thickness of 0.649 nm and an energy gap of 1.64 eV, absorb less than 10 % of incoming light. Therefore, increasing the amount of light absorption in monolayers of WSe₂ and other transition metal dicalcogenides has become an important issue for practical applications in electronic and photonic devices. One solution is the integration of these monolayers and surface plasmon structures. In this paper, we upgrade light absorption in visible and near infrared area to broad band mode by designing a simple unit cell. It is found that the mean absorption of the proposed absorber in the wavelength range of 600 – 850 nm is about 93 %. We have to mention that these simulations have been done by Lumrical software that is based on discretization of Maxwell equations in time and space domains based on the finite difference time domain method.
ISSN:1682-6957
2345-3664
DOI:10.47176/ijpr.23.2.41676