Your search keyword '"Michael Mrejen"' showing total 2 results

1. Low-loss and energy efficient modulation in silicon photonic waveguides by adiabatic elimination scheme

Author

Michael Mrejen, Yuan Wang, Haim Suchowski, Nicolas Bachelard, and Xiang Zhang

Subjects

Silicon photonics, Materials science, Physics and Astronomy (miscellaneous), Silicon, business.industry, Physics::Optics, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, Waveguide (optics), 010309 optics, 020210 optoelectronics & photonics, Optical modulator, Optics, Relatively compact subspace, chemistry, 0103 physical sciences, Broadband, 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, Adiabatic process, business, Efficient energy use

Abstract

High-speed Silicon Photonics calls for solutions providing a small footprint, high density, and minimum crosstalk, as exemplified by the recent development of integrated optical modulators. Yet, the performances of such modulators are hindered by intrinsic material losses, which results in low energy efficiency. Using the concept of Adiabatic Elimination, here, we introduce a scheme allowing for the low-loss modulation in densely packed waveguides. Our system is composed of two waveguides, whose coupling is mediated by an intermediate third waveguide. The signal is carried by the two outer modes, while the active control of their coupling is achieved via the intermediate dark mode. The modulation is performed by the manipulation of the central-waveguide mode index, leaving the signal-carrying waveguides unaffected by the loss. We discuss how Adiabatic Elimination provides a solution for mitigating signal losses and designing relatively compact, broadband, and energy-efficient integrated optical modulators.

Published

2017

2. Interacting dark resonances with plasmonic meta-molecules

Author

Michael Mrejen, Xiaobo Yin, Yuan Wang, Xiang Zhang, Pankaj K. Jha, Jeongmin Kim, and Chihhui Wu

Subjects

Physics, Quantum optics, Physics and Astronomy (miscellaneous), Condensed matter physics, Physics::Optics, Resonance, Molecular physics, Photonic metamaterial, Coupling (physics), Dark state, Excited state, Atom, Physics::Atomic and Molecular Clusters, Plasmon

Abstract

Dark state physics has led to a variety of remarkable phenomena in atomic physics, quantum optics, and information theory. Here, we investigate interacting dark resonance type physics in multi-layered plasmonic meta-molecules. We theoretically demonstrate that these plasmonic meta-molecules exhibit sub-natural spectral response, analogous to conventional atomic four-level configuration, by manipulating the evanescent coupling between the bright and dark elements (plasmonic atoms). Using cascaded coupling, we show nearly 4-fold reduction in linewidth of the hybridized resonance compared to a resonantly excited single bright plasmonic atom with same absorbance. In addition, we engineered the geometry of the meta-molecules to realize efficient intramolecular excitation transfer with nearly 80%, on resonant excitation, of the total absorption being localized at the second dark plasmonic atom. An analytical description of the spectral response of the structure is presented with full electrodynamics simulations to corroborate our results. Such multilayered meta-molecules can bring a new dimension to higher quality factor plasmonic resonance, efficient excitation transfer, wavelength demultiplexing, and enhanced non-linearity at nanoscale.

Published

2014