報告題目: Lithium niobate nanophotonics – giving new life to an old material
Dr. Cheng Wang is an Assistant Professor of Electronic Engineering at City University of Hong Kong. He received his B.S. degree in Microelectronics from Tsinghua University in 2012. Afterwards, he joined Harvard University as a Ph.D. student in the School of Engineering and Applied Sciences, advised by Prof. Marko Loncar. He received his S.M. and Ph.D. degrees, both in Electrical Engineering from Harvard University, in May 2015 and May 2017, respectively. From 2017 – 2018, Cheng conducted research as a postdoctoral fellow at Harvard, before joining City University of Hong Kong in June 2018. Cheng's research focuses on enhancing light-matter interaction in nanophotonic structures. His current research effort focuses on realizing integrated lithium niobate photonic circuits for applications in optical communications and nonlinear optics.
Lithium niobate (LN) is an excellent nonlinear optical material widely deployed for telecommunications and wavelength conversion. While its high χ2 nonlinearity, wide transparency window and low optical loss offer unique advantages, conventional LN devices are bulky and discrete due to the low index-contrast in ion-exchanged waveguides. In this talk, I will provide a summary of our recent breakthrough in integrated LN photonics that overcomes this limitation by direct etching thin-film LN. We show that waveguides and resonators with sub-wavelength light confinement and extremely low propagation loss (< 0.03 dB/cm) can be fabricated using standard lithography techniques. Together with the strong electro-optic and nonlinear responses, we demonstrate electro-optic modulators with CMOS-compatible driving voltage of 1.4 V and electro-optic bandwidths up to 100 GHz. Leveraging the high nonlinear-optic coefficient, we demonstrate broadband Kerr and electro-optic frequency comb generation, as well as nonlinear wavelength conversion with record-high conversion efficiencies. The high-performance LN nanophotonic platform could open up avenues for a chip-scale photonic integrated circuit densely integrated with non-classic light sources, high-speed switches, filters and wavelength converters, which could find applications in next-generation optical data links, quantum communications and microwave/terahertz photonics.