Litcius/Paper detail

Applied electromagnetic optics simulations for nanophotonics

Nicklas Anttu, Henrik Mäntynen, Anastasiia Sorokina, Jari Turunen, Toufik Sadi, Harri Lipsanen

2021Journal of Applied Physics25 citationsDOIOpen Access PDF

Abstract

Nanophotonics—the science and technology of confining, guiding, and making photons interact with matter at the nanoscale—is an active research field. By varying the geometry and constituent materials, nanostructures allow precise control of the scattering of incident light and tailoring of emitted light. In this Tutorial, we outline the use of the Maxwell equations to model the optical response of nanostructures. This electromagnetic optics approach uses the refractive indices of the constituent materials and the geometry of the nanostructures as input. For most nanostructure geometries, analytical solutions to the Maxwell equations are not available. Therefore, we discuss varying computational methods for solving the equations numerically. These methods allow us to simulate the optical response of nanostructures, as needed for design optimization and analysis of characterization results.

Topics & Concepts

NanophotonicsNanostructureMaxwell's equationsPhysical opticsElectromagnetic fieldRayPhysicsPhotonGeometrical opticsNanoscopic scaleElectromagnetic radiationScatteringElectromagneticsField (mathematics)Computational electromagneticsOpticsClassical mechanicsEngineering physicsQuantum mechanicsMathematicsPure mathematicsPlasmonic and Surface Plasmon ResearchPhotonic Crystals and ApplicationsPhotonic and Optical Devices
Applied electromagnetic optics simulations for nanophotonics | Litcius