報告題目:硅基納米光子器件
報告時間:9月29日下午14:00-16:00
地點:賽博南樓412會議室。
報告人:戴道鋅(浙江大學教授,國家杰青)
報告人簡介:
戴道鋅,浙江大學求是特聘教授/光電學院副院長、國家杰出青年科學基金獲得者。長期致力于高性能與高集成度硅基集成光子器件及應用研究,發展了硅基非對稱光波導及器件新結構和新機理,實現了一系列高集成度高性能的偏振調控、模式復用、可調諧-切換器件及其功能集成,解決了如何突破單一復用技術容量限制并實現其可重構性等問題,先后獲得浙江省科學技術一等獎、中國儀器儀表學會金國藩青年學子獎、浙江省青年科技獎、浙江省高校科研成果獎、國家優秀青年科學基金、國家杰出青年科學基金等獎勵或榮譽。
發表國際SCI期刊論文170余篇,包括作為第一/通訊作者在Nature Communications、Proceedings of the IEEE、Light: Science & Applications、Laser & Photonics Reviews、ACS Nano、Optica等著名光學期刊發表140余篇。其成果被國內外同行廣泛引用,論文SCI引用4500余次,單篇最高SCI引用320余次并入選了美國光學學會期刊《Optics Express》創刊20周年百篇高引論文,連續入選了2015-2018年愛思唯爾《中國高被引學者榜單》(物理學和天文學學科)。應邀在光通信領域頂級學術會議-美國OFC、集成光學領域頂級會議-IPR等特邀報告60余次,擔任ACP等技術委員會主席/共同主席以及頂級會議-美國OFC等技術委員會委員30余次。應邀擔任了IEEE Photonics Technology Letters、Optical and Quantum Electronics、Photonics Research等國際SCI期刊副主編/執行主編。
報告摘要:
The demand for data has been increasing exponentially with very high growth rates from the access to data-centre interconnects and to long-haul transmissions. Further enhancement of the information capacity has been a perennial goal of scientists and engineering globally. A cost-effective solution for expanding the link capacity of optical interconnects is utilizing advanced multiplexing technologies. Currently, the most popular technologies include wavelength-division-multiplexing (WDM), polarization-division-multiplexing (PDM), mode-division-multiplexing (MDM), etc. As it is well known, silicon photonics is compatible with standard CMOS (complementary metal oxide semiconductor) processes and thus has attracted much attention as a very promising platform to build ultrasmall integrated photonic devices for large-scale photonic integrated circuits in the future. Silicon-based on-chip (de)multiplexers are really attractive and great progresses have been achieved in the past years, which will be reviewed in the talk. There are three parts. The first part is for high-performance wavelength-division-multiplexers, including arrayed-waveguide gratings (AWGs) and microring-resonators (MRRs) as the representatives. The second part is for high-performance PDM devices like polarizers, polarization-beam splitters (PBSs) and polarization rotators (PRs) as the representative on-chip polarization-handling devices. The third part for mode converters/ (de)multiplexers. Hybrid (de)multiplexers enabling more than one multiplexing technologies simultaneously will be discussed. As the link capacity increases dramatically, it is also becoming more and more important to develop smart photonic networks-on-chip so that the bandwidth/channels can be utilized optimally and flexible. One of the keys for realizing smart (reconfigurable) photonic networks is switchable / tunable photonic integrated devices. As silicon has a large thermo-optic (TO) coefficient as well as the large heat conductivity (~149W/m?K), it is promising to realize efficient thermally-switchable/tunable silicon-based photonic integrated devices with reduced power consumption. Our recent work on thermally-switchable / tunable silicon photonic devices with micro-/nano-heaters will be also reviewed.
References:
[1]Dai*, “Silicon Nanophotonic Integrated Devices for On-chip Multiplexing and Switching,” IEEE/OSA Journal of Lightwave Technology, 35(4): 572-587, 2016(Invited).
[2]Dai* et al. "Silicon-based on-chip multiplexing technologies and devices for Peta-bit optical interconnects," Nanophotonics, 3(4-5): 283–311, 2014 (invited).
[3]Dai et al. “Polarization management for silicon photonic integrated circuits,” Laser & Photonics Reviews 7(3):303-328, 2013 (invited).
[4]Dai*, et al. “Passive technologies for future large-scale photonic integrated circuits on silicon: polarization handling, light non-reciprocity, and loss reduction,” Light: Science and Applications, 1: 1-12, 2012 (invited).
光電學院
2018年9月27日
