Title :
Numerical Analysis of Carrier-Depletion Strained SiGe Optical Modulators With Vertical p-n Junction
Author :
Younghyun Kim ; Takenaka, Mitsuru ; Takagi, Shinichi
Author_Institution :
Dept. of Electr. Eng. & Inf. Syst., Univ. of Tokyo, Tokyo, Japan
Abstract :
The modulation characteristics of carrier-depletion strained SiGe optical modulators with a vertical p-n junction are numerically analyzed by technology computer-aided design simulation and finite-difference optical mode analysis. In addition to the strong optical confinement in the vertical direction for the fundamental transverse electric field mode, the vertical p-n junction effectively depletes the strained SiGe layer in which the plasma dispersion effect is enhanced owing to the mass modulation of holes by strain. We predict that a Si0.7Ge0.3 optical modulator exhibits VπL at 1.55 μm of as small as 0.31 V-cm at a bias voltage of -2 V, which is ~1.8 times smaller than that of a Si optical modulator. The product of VπL and the phase-shifter loss (αVπL) is also expected to be as low as 18.3 V-dB at -2 V, enabling optical modulation with a 5-dB extinction ratio in a symmetric Mach-Zehnder modulator.
Keywords :
Ge-Si alloys; finite difference methods; optical design techniques; optical losses; optical modulation; p-n junctions; semiconductor materials; technology CAD (electronics); SiGe; bias voltage; carrier-depletion strained optical modulators; extinction ratio; finite-difference optical mode analysis; fundamental transverse electric field mode; hole mass modulation; modulation characteristics; numerical analysis; optical confinement; phase-shifter loss; plasma dispersion effect; strained layer; symmetric Mach-Zehnder modulator; technology computer-aided design simulation; vertical direction; vertical p-n Junction; voltage -2 V; wavelength 1.55 mum; High-speed optical techniques; Optical modulation; Optical waveguides; P-n junctions; Silicon; Silicon germanium; Si photonics; Strained SiGe; optical modulator; vertical $p$ - $n$ junction;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2015.2405931
