PRESENTATION
Quantum Dot Lasers on Silicon for Highly Parallel Data Transmission
Quantum dot lasers offer a variety of useful characteristics as light sources in integrated highly parallel data transmission links. These properties include low threshold, high efficiency, resilience to unintentional optical feedback, high reliability, and broad wavelength spectral emission. The combination of these lasers with sophisticated silicon photonics components presents a variety of circuit architectures for highly compact, high bandwidth, and highly efficient photonic transmitters with low power consumption which are fabricated in a low cost and high volume commercial foundry. This presentation will provide an overview of the laser and circuit designs enabled by this platform.
Michael Davenport
Quintessent
Michael graduated with his Ph.D in Electrical Engineering from the University of California, Santa Barbara in 2017 after completing extended internships with Air Force Research Labs at Kirkland Airforce Base and Intel Labs in Santa Clara. Since then, he worked at Ayar Labs from 2017 to 2019 as the laser department before joining Quintessent. Outside of work, he is an avid amateur powerlifter and enjoys spending time with his pet poodle.