Title :
Enhanced performance in traveling-wave electroabsorption Modulators based on undercut-etching the active-region
Author :
Chiu, Yi-Jen ; Wu, Tsu-Hsiu ; Cheng, Wen-Chin ; Lin, F.J. ; Bowers, John E.
Author_Institution :
Inst. of Electro-Opt. Eng., Nat. Sun Yat-Sen Univ., Kaohsiung, Taiwan
Abstract :
A novel traveling-wave electroabsorption modulator (TWEAM) based on undercut-etching-active-region waveguide (UEAW) is proposed and demonstrated. By selectively wet-etching the InGaAsP from InP to reduce InGaAsP active region, the waveguide can reduce parasitic capacitance with high conductivity in n-InP and p-InP cladding layers. In comparison with conventional ridge-waveguide (RW) TWEAM, 3 dB lower optical-insertion-loss, at least 6 dB higher in radio-frequency-link gain (dc to 40 GHz), and faster electrooptical response (3-dB bandwidth of 25 GHz at 50 Ω-termination for UEAW and 15 GHz for RW) are obtained in UEAW-TWEAM. A 10-Gbs/s operation with low swing voltage of 0.6 V has been achieved in UEAW-TWEAM, a 3.2-dB enhancement over RW-TWEAM. It indicates the tradeoff in designing electroabsorption modulators can be greatly released.
Keywords :
III-V semiconductors; claddings; electro-optical modulation; electroabsorption; etching; gallium arsenide; gallium compounds; indium compounds; integrated optics; optical design techniques; optical fibre communication; optical losses; optical waveguides; ridge waveguides; 0.6 V; 10 Gbit/s; 15 GHz; 25 GHz; 50 ohm; InGaAsP; InGaAsP active region; InP; active-region waveguide; cladding layers; conductivity; electroabsorption modulators; electrooptical response; optical-insertion-loss; parasitic capacitance reduction; radiofrequency-link gain; traveling-wave modulators; undercut-etching; wet-etching; Bandwidth; Extinction ratio; High speed optical techniques; Optical losses; Optical modulation; Optical waveguides; PIN photodiodes; Parasitic capacitance; Semiconductor waveguides; Stimulated emission; Electroabsorption; high efficiency; high speed; modulator; semiconductor; traveling wave; undercut etching;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2005.856377
