Doylend J K, Jessop P E, Knights A P
Department of Engineering Physics, McMaster University, Hamilton, Ontario, L8S 4L7, Canada.
Opt Express. 2010 Jul 5;18(14):14671-8. doi: 10.1364/OE.18.014671.
We describe, model and demonstrate a tunable micro-ring resonator integrated monolithically with a photodiode in a silicon waveguide device. The photodiode is made sensitive to wavelengths at and around 1550nm via the introduction of lattice damage through selective ion implantation. The ring resonator enhances detector responsivity in a 60 mum long waveguide photodiode such that it is 0.14 A/W at -10Vbias with less than 0.2 nA leakage current. The device is tunable such that resonance (and thus detection) can be achieved at any wavelength from 1510 - 1600 nm. We also demonstrate use of the device as a digital switch with integrated power monitoring, 20 dB extinction, and no optical power tapped from the output path to the photodiode. A theoretical description suggests that for a critically coupled resonator where the round trip loss is dominated by the excess defects used to mediate detection, the maximum responsivity is independent of device length. This leads to the possibility of extremely small detector geometries in silicon photonics with no requirement for the use of III-V materials or germanium.
我们描述、建模并展示了一种在硅波导器件中与光电二极管单片集成的可调谐微环谐振器。通过选择性离子注入引入晶格损伤,使光电二极管对1550nm及附近波长敏感。环形谐振器提高了60μm长波导光电二极管的探测器响应度,在-10V偏压下响应度为0.14A/W,漏电流小于0.2nA。该器件是可调谐的,使得在1510 - 1600nm的任何波长下都能实现共振(进而实现检测)。我们还展示了该器件作为具有集成功率监测、20dB消光比且无光功率从输出路径耦合到光电二极管的数字开关的应用。理论描述表明,对于临界耦合谐振器,其中往返损耗主要由用于介导检测的过量缺陷决定,最大响应度与器件长度无关。这使得在硅光子学中有可能实现极小的探测器几何尺寸,而无需使用III-V族材料或锗。