Efficient modelling techniques in nanophotonics

We describe some recent developments in the efficient modelling of light-matter interactions in plasmonics and nanophotonics. In particular, we describe an efficient finite-difference time-domain (FDTD) method to compute regularized quasinormal modes in resonant photonic structures, which have a wide range of applications in classical and quantum nanophotonics, and present methods to compute disorder-induced localization modes (Anderson localization) in slow light photonic crystal waveguides.

Efficient modelling techniques in nanophotonics

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Parametric Wavelength Conversion in Waveguiding Structures: Efficiency, Bandwidth and Polarization

Orientation-dependent two-dimensional magnonic crystal modes in an ultralow-damping ferrimagnetic waveguide containing repositioned hexagonal lattices of Cu disks

High density lithium niobate photonic integrated circuits

Parametric Wavelength Conversion in Waveguiding Structures: Efficiency, Bandwidth and Polarization

Orientation-dependent two-dimensional magnonic crystal modes in an ultralow-damping ferrimagnetic waveguide containing repositioned hexagonal lattices of Cu disks

High density lithium niobate photonic integrated circuits