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High-speed silicon electrooptic Modulator design

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F. Gan; F.X. Kartner
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Abstract:

An electrically driven Mach-Zehnder waveguide modulator based on high-index contrast silicon split-ridge waveguide technology and electronic carrier injection is proposed...Show More

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Abstract:

An electrically driven Mach-Zehnder waveguide modulator based on high-index contrast silicon split-ridge waveguide technology and electronic carrier injection is proposed. The excellent optical and carrier confinement possible in high-index contrast waveguide devices, together with good thermal heat sinking and forward biased operation, enables high-speed modulation with small signal modulation bandwidths beyond 20 GHz, a V/sub /spl pi// times length figure of merit of V/sub /spl pi//L=0.5 V/spl middot/cm and an insertion loss of about 4 dB. The modulator can be fabricated in a complementary metal-oxide-semiconductor compatible way.
Published in: IEEE Photonics Technology Letters ( Volume: 17, Issue: 5, May 2005)
Page(s): 1007 - 1009
Date of Publication: 25 April 2005

ISSN Information:

DOI: 10.1109/LPT.2005.846756
Citations are not available for this document.
Contents

I. Introduction

The DEVELOPMENT of future electronic–photonic integrated circuits based on silicon (Si) technology critically depends on the availability of complementary metal–oxide–semiconductor (CMOS)-compatible high-speed modulators that enable the interaction of electronic and optical signals. (a) Externally biased MZ modulator with coplanar RF feeder. (b) Split-ridge waveguide pin-phase modulator with single-mode intensity profile. Si-based phase modulators using the plasma dispersion effect in a -structure have been proposed for Si-based optoelectronic phase and amplitude modulators [1]. Switching speeds up to 10 MHz [2] have been demonstrated and up to 1 GHz are predicted [3]. The speed of the response in these devices is limited by carrier recombination. Very recently a modulator based on an MOS structure has been proposed [4] operating at 1-GHz speed. However, this device needs an applied voltage of 10 V for achieving a phase shift within 1-cm length and showed 6.7-dB loss due to the doped polysilicon rib-waveguide. Much lower drive voltage in the order of 1–5 V is needed, when fed by CMOS circuitry. The same is true for top contacted rib-waveguides of previously proposed pin-structures [1].

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