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|dc.title||Low thermal budget monolithic integration of evanescent-coupled Ge-on-SOI photodetector on Si CMOS platform|
|dc.identifier.citation||Ang, K.-W., Liow, T.-Y., Yu, M.-B., Fang, Q., Song, J., Lo, G.-Q., Kwong, D.-L. (2010-01). Low thermal budget monolithic integration of evanescent-coupled Ge-on-SOI photodetector on Si CMOS platform. IEEE Journal on Selected Topics in Quantum Electronics 16 (1) : 106-113. ScholarBank@NUS Repository. https://doi.org/10.1109/JSTQE.2009.2025142|
|dc.description.abstract||The design and fabrication of a monolithically integrated evanescent-coupled Ge-on-silicon-on-insulator (SOI) photodetector and CMOS circuits were realized on common SOI platform using an electronic-first and photonic-last integration approach. High-performance detector with an integrated Si waveguide was demonstrated on epitaxial Ge-absorbing layer selectively grown on an ultrathin SOI substrate. Performance metrics of photodetector designs featuring vertical and lateral PIN configurations were investigated. When operated at a bias of 1.0 V, a vertical PIN detector achieved a lower I-dark of 0.57 A as compared to a lateral PIN detector, a value that is below the typical $\sim$ 1 $\mu$A upper limit acceptable for high-speed-receiver design. Very high responsivity of $\sim$0.92 A/W was obtained in both detector designs for a wavelength of 1550 nm, which corresponds to a quantum efficiency of ∼73%. Impulse response measurements showed that the vertical PIN detector gives rise to a smaller full-width at half-maximum of ∼ 24.4 ps over a lateral PIN detector, which corresponds to a 3 dB bandwidth of ∼11.3 GHz. RC time delay is shown to be the dominant factor limiting the speed performance. Eye patterns (pseudorandom binary sequence 27-1) measurement further confirms the achievement of high-speed and low-noise photodetection at a bit rate of 8.5 Gb/s. Excellent transfer and output characteristics have also been achieved by the integrated CMOS inverter circuits in addition to the well-behaved logic functions. The introduction of an additional thermal budget (800 °C) arising from the Ge epitaxy growth has no observable detrimental impact on the short-channel control of the CMOS inverter circuit. In addition, we describe the issues associated with monolithic integration and discuss the potential of Ge-detector/Si CMOS receiver for future optical communication applications. © 2006 IEEE.|
|dc.contributor.department||ELECTRICAL & COMPUTER ENGINEERING|
|dc.description.sourcetitle||IEEE Journal on Selected Topics in Quantum Electronics|
|Appears in Collections:||Staff Publications|
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