Fast and Efficient Type-II Phototransistors Integrated on Silicon

Increasing the efficiency and reducing the footprint of on-chip photodetectors enables dense optical interconnects for emerging computational and sensing applications. Avalanche photodetectors (APD) are currently the dominating on-chip photodetectors. However, the physics of avalanche multiplication leads to low energy efficiencies and prevents device operation at a high gain, due to a high excess noise, resulting in the need for electrical amplifiers. These properties significantly increase power consumption and footprint of current optical receivers. In contrast, heterojunction phototransistors (HPT) exhibit high efficiency and very small excess noise at high gain. However, HPT's gain-bandwidth product (GBP) is currently inferior to that of APDs at low optical powers. Here, we demonstrate that the type-II energy band alignment in an antimony-based HPT results in a significantly smaller junction capacitance and higher GBP at low optical powers. We used a CMOS-compatible heterogeneous integration method to create compact optical receivers on silicon with an energy efficiency that is about one order of magnitude higher than that of the best reported integrated APDs on silicon at a similar GBP of 270 GHz. Bitrate measurements show data rate spatial density above 800 Tbps per mm2, and an energy-per-bit consumption of only 6 fJ/bit at 3 Gbps. These unique features suggest new opportunities for creating highly efficient and compact on-chip optical receivers based on devices with type-II band alignment.