High-channel-count 20 GHz passively mode locked quantum dot laser directly grown on Si with 4.1 Tbit/s transmission capacity
Songtao Liu, Xinru Wu, Daehwan Jung, Justin C. Norman, Mj Kennedy, Hon, K. Tsang, Arthur C. Gossard, John E. Bowers

TL;DR
This paper reports a novel high-channel-count 20 GHz passively mode-locked quantum dot laser grown on silicon, achieving record low noise, wide bandwidth, and over 4 terabits per second transmission capacity for on-chip optical interconnects.
Contribution
First demonstration of a low noise, high-channel-count quantum dot laser on silicon with record performance metrics and multi-terabit transmission capacity.
Findings
Achieved 82.7 fs timing jitter and 1.8 kHz RF linewidth.
Produced a 6.1 nm optical comb with 58 lines.
Enabled 4.1 Tbit/s data transmission using 64 channels.
Abstract
Low cost, small footprint, highly efficient and mass producible on-chip wavelength-division-multiplexing (WDM) light sources are key components in future silicon electronic and photonic integrated circuits (EPICs) which can fulfill the rapidly increasing bandwidth and lower energy per bit requirements. We present here, for the first time, a low noise high-channel-count 20 GHz passively mode-locked quantum dot laser grown on complementary metal-oxide-semiconductor compatible on-axis (001) silicon substrate. The laser demonstrates a wide mode-locking regime in the O-band. A record low timing jitter value of 82.7 fs (4 - 80 MHz) and a narrow RF 3-dB linewidth of 1.8 kHz are measured. The 3 dB optical bandwidth of the comb is 6.1 nm (containing 58 lines, with 80 lines within the 10 dB bandwidth). The integrated average relative intensity noise values of the whole spectrum and a single…
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