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Based on the coupled mode theory and on other analytical and semi-analytical methods we model the propagation of electromagnetic waves in dielectric integrated optical circuits. ..more..

Arrays of metallic nanoparticles are used to enhance the nonlinear and chiral properties of the material. This leads to second harmonic light emission or dichroism. ..more..

We calculate and compare EEL (electron energy loss) spectroscopy and CL (cathodoluminescence) spectra of plasmonic nanoparticles.  ..more..

We co-operate with the group of Prof. Dr. Christian Plessl and the PC2 to develop tools for efficient use of parallel hardware as FPGAs and GP-GPUs for scientific computing. ..more..

We design antennas on the nano- and micro-scale that allow steering the light either to desired directions or to drastically enhance fields locally. ..more..

We use and extend the Time Domain Discontinuous Galerkin method to perform the challenging multi-scale simulations  in many of our projects. ..more..

We simulate the scattering of electromagnetic fields at dust and ice particles as found in industrial environments but even more in interplanetary space.  ..more..

We describe the nonlinear optical dynamics in tailored quantum dots. ..more..

We model the resonant interference in photonic crystals and other photonic resonators as optical microdisks to control the flow of light and to capture it. ..more..