van der Jjgm Jos Tol scite author profile

Abstract:A uni-traveling carrier photodetector (UTC-PD), heterogeneously integrated on silicon, is demonstrated. It is fabricated in an InP-based photonic membrane bonded on a silicon wafer, using a novel double-sided processing scheme. A very high 3 dB bandwidth of beyond 67 GHz is obtained, together with a responsivity of 0.7 A/W at 1.55 µm wavelength. In addition, open eye diagrams at 54 Gb/s are observed. These results promise high speed applications using a novel full-functionality photonic platform on silicon. Tol, H. Ambrosius, G. Roelkens, and M. Smit, "Low-optical-loss, low-resistance Ag/Ge based ohmic contacts to n-type InP for membrane based waveguide devices," Opt. Mater. Express 5(2), 393-398 (2015). 24. A. Higuera-Rodriguez, V. Dolores-Calzadilla, Y. Jiao, E. J. Geluk, D. Heiss, and M. K. Smit, "Realization of efficient metal grating couplers for membrane-based integrated photonics," Opt. Lett. 40(12), 2755Lett. 40(12), -2757Lett. 40(12), (2015.

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All-optical switching due to state filling in quantum dots

Prasanth

Haverkort

Deepthy

et al. 2004

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Photonic integration in indium-phosphide membranes on silicon

et al. 2011

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A new photonic integration technique is presented, which enables the use of indium-phosphide-based membranes on top of silicon chips. This can provide the electronic chips (complementary metal-oxide semiconductor (CMOS)) with an added optical layer (indium-phosphide membrane on silicon (IMOS)) for resolving the communication bottleneck. Very small passive devices have been realised, with performances comparable to other membrane devices (propagation loss 7 dB/cm, negligible bending loss for micron size radii, 3 dB splitter with 0.6 dB excess loss, resonator with Q-factor of 15.500). Also, a new passive device is introduced, a 4.12 micron long polarisation converter which in simulations promises broadband performance and tolerant fabrication. Finally, an active/passive regrowth technique is investigated for submicron active regions within an otherwise mostly passive membrane. A good morphology is obtained around the interfaces between the active and passive regions. The processing involved did not damage the materials severely, so that light emission in micro-PL measurements was found. However, an increasing blue shift with decreasing size occurred, due to quantum well intermixing. Optimising the design and the processing can take care of this. Taken together, the results presented here show that it is feasible to realise extremely small passive and active devices in a photonic circuit in an InP membrane

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