Strain-tunable silicon photonic band gap microcavities in optical waveguides
- 23 February 2004
- journal article
- research article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 84 (8), 1242-1244
- https://doi.org/10.1063/1.1649803
Abstract
We report the design, device fabrication, and measurements of tunable silicon photonic band gap microcavities in optical waveguides, using direct application of piezoelectric-induced strain to the photonic crystal. We show, through first-order perturbation computations and experimental measurements, a 1.54 nm shift in cavity resonances at 1.56 μm wavelengths for an applied strain of 0.04%. The strain is applied through integrated piezoelectric microactuators. For operation at infrared wavelengths, we combine x-ray and electron-beam lithography with thin-film piezoelectric processing. This level of integration permits realizable silicon-based photonic chip devices, such as high-density optical filters, with active reconfiguration.Keywords
This publication has 13 references indexed in Scilit:
- Perturbation theory for Maxwell’s equations with shifting material boundariesPhysical Review E, 2002
- Design of photonic crystal microcavities for cavity QEDPhysical Review E, 2001
- Polarization Mode Control of Two-Dimensional Photonic Crystal Laser by Unit Cell Structure DesignScience, 2001
- Strain-tunable photonic band gap crystalsApplied Physics Letters, 2001
- Strain effects and phase transitions in photonic resonator crystalsNature, 2000
- Tunable Photonic Crystals with Semiconducting ConstituentsPhysical Review Letters, 2000
- Temperature tuning of the stop band in transmission spectra of liquid-crystal infiltrated synthetic opal as tunable photonic crystalApplied Physics Letters, 1999
- Liquid-Crystal Photonic-Band-Gap Materials: The Tunable Electromagnetic VacuumPhysical Review Letters, 1999
- Two-dimensional tunable photonic crystalsPhysical Review B, 1998
- Photonic-bandgap microcavities in optical waveguidesNature, 1997