Design and analysis of separate-absorption-transport-charge-multiplication traveling-wave avalanche photodetectors |
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Authors: | Jin-Wei Shi Yin-Hsin Liu Chee-Wee Liu |
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Affiliation: | Dept. of Electr. Eng., Nat. Central Univ., Taoyuan, Taiwan; |
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Abstract: | This paper proposes a novel type of avalanche photodiode-the separate-absorption-transport-charge-multiplication (SATCM) avalanche photodiode (APD). The novel design of photoabsorption and multiplication layers of APDs can avoid the photoabsorption layer breakdown and hole-transport problems, exhibit low operation voltage, and achieve ultra-high-gain bandwidth product performances. To achieve low excess noise and ultra-high-speed performance in the fiber communication regime (1.3/spl sim/1.55 /spl mu/m), the simulated APD is Si-based with an SiGe-Si superlattice (SL) as the photoabsorption layer and traveling-wave geometric structures. The frequency response is simulated by means of a photo-distributed current model, which includes all the bandwidth-limiting factors, such as the dispersion of microwave propagation loss, velocity mismatch, boundary reflection, and multiplication/transport of photogenerated carriers. By properly choosing the thicknesses of the transport and multiplication layers, microwave propagation effects in the traveling-wave structure can be minimized without increasing the operation voltage significantly. A near 30-Gb/s electrical bandwidth and 10/spl times/ avalanche gain can be achieved simultaneously, even with a long device absorption length (150 /spl mu/m) and low operation voltage (/spl sim/12 V). In addition, the ultrahigh output saturation power bandwidth product of this simulated TWAPD structure can also be expected due to the large photoabsorption volume and superior microwave-guiding structure. |
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