Abstract
Over the years, photonic components have grown in both complexity and function. Photonic device architectures have dimensions that are much smaller than the wavelength of operation, and employ dense integration, along with the use of novel two-dimensional materials and physical effects to control optical properties and light-matter interaction. These developments have gone hand in hand with advances in computational methods that can model the behavior of light and be used to optimize designs. At times, the computational methods were more advanced than experimental techniques and realization. At others, the need to accurately predict performance and understand the physics at play in the new components/materials prompted progress in modeling methods, so much so that commercial modeling software is now an integral part of photonics.
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