报告题目：All-dielectric nanophotonics: materials, designs, and applications 

报 告 人：Prof. Sergey Makarov 威斯尼斯人app官方下载（青岛） 

时 间：4 月 4 日（星期二） 上午 10:00-11:00 (Apr. 4, 10:00-11:00 a.m.)  

会议地点：理学楼 212 会议室 (Room 212, Science Building) 

主办单位：威斯尼斯人app官方下载 College of Physics and Optoelectronic                         Engineering 

承办单位：纤维集成光学教育部重点实验室  

    “面向工程应用的微结构功能光纤”学科创新引智基地 

报告人简介：Sergey Makarov received a Ph.D. degree in 2014 at the Lebedev Physical Institute of the Russian Academy of Sciences  (Moscow, Russia), and Habilitated at the ITMO University in 2018 (St. Petersburg, Russia). Currently, he is Professor, Head of Laboratory of Hybrid Nanophotonics and Optoelectronics at ITMO University, Dean of Faculty of Photonics at ITMO University, as well as Director of Shared Research Facilities on Nanotechnology at the ITMO University. In 2022, he was appointed as a Professor at Qingdao Innovation and Development Center of Harbin Engineering University. The topics of his research activity include nanophotonics, halide perovskites, laser-matter interaction, nanotechnology, and optoelectronics. He is co-author of more than 300 publications, including Chemical Reviews, Advanced Materials, ACS Nano, Nano Letters, and in many other high-level journals. Sergey Makarov is also an Editorial Board member of Opto-Electronic Advances journal, and in Advisory Board of journals of ACS and Wiley publishers. 

报告简介：Nanophotonics and meta-optics based on optically resonant all-dielectric structures is a rapidly developing research area driven by its potential applications for low-loss efficient metadevices. Many materials were applied to create advanced all-dielectric nanophotonic designs, including Si, GaAs, GaP, TiO2, and many others. Recently, the study of halide perovskites has attracted enormous attention due to their exceptional optical and electrical properties. As a result, this family of materials can provide a prospective platform for modern all-dielectric nanophotonics and meta optics, allowing us to overcome many obstacles associated with the use of conventional semiconductor materials. Finally, we overview the recent progress in such applications of all-dielectric nanophotonics as optical heating, nanothermometry, light-emitting nanoantennas, nanolasers, surface coloration, anti-reflection, optical information encoding, and photovoltaics