Roadmap for Gain-Bandwidth-Product Enhanced Photodetectors

TL;DR

This paper discusses the fundamental limits and design strategies for high-performance photodetectors, emphasizing the potential of nanometer-thin materials and innovative device architectures to significantly enhance gain-bandwidth product.

Contribution

It introduces a scaling length theory framework for photodetector design, proposing novel approaches like short-channel and heterojunction structures to surpass current GBP limitations.

Findings

Two-dimensional materials can enable 100 GHz response rates.

Short-channel and slot-waveguide designs improve detector performance.

Targeting GBP of 10^12 Hz-A/W for next-generation photodetectors.

Abstract

Photodetectors are key optoelectronic building blocks performing the essential optical-to-electrical signal conversion, and unlike solar cells, operate at a specific wavelength and at high signal or sensory speeds. Towards achieving high detector performance, device physics, however, places a fundamental limit of the achievable detector sensitivity, such as responsivity and gain, when simultaneously aimed to increasing the detectors temporal response, speed, known as the gain-bandwidth product (GBP). While detectors GBP has been increasing in recent years, the average GBP is still relatively modest (~10^6-10^7 Hz-A/W). Here we discuss photodetector performance limits and opportunities based on arguments from scaling length theory relating photocarrier channel length, mobility, electrical resistance with optical waveguide mode constrains. We show that short-channel detectors are synergistic with slot-waveguide approaches, and when combined, offer a high-degree of detector design synergy especially for the class of nanometer-thin materials. Indeed, we find that two dimensional material-based detectors are not limited by their low mobility and can, in principle, allow for 100 GHz fast response rates. However, contact resistance is still a challenge for such thin materials, a research topic that is still not addressed yet. An interim solution is to utilize heterojunction approaches for functionality separation. Nonetheless, atomistically- and nanometer-thin materials used in such next-generation scaling length theory based detectors also demand high material quality and monolithic integration strategies into photonic circuits including foundry-near processes. As it stands, this letter aims to guide the community if achieving the next generation photodetectors aiming for a performance target of GBP = 10^12 Hz-A/W.