Gender: Female
Title: Associate Professor
Education: Doctoral student
Discipline: Instrument Science and Technology
Research interests: Laser Manufacturing and Detection, optical quantum devices
E-mail: xukemi@bit.edu.cn
Xu Kemi, female, born in Gongzhuling City, Jilin Province in January 1984, Ph.D., studied in Australia from 2014 to 2020, won the Postdoctoral President Scholarship of Global Talent Program of University of New South Wales in Australia in 2014, joined Beijing Institute of Technology in 2020, was hired as a doctoral supervisor in 2020, and was selected as a national Young Talent Program in 2022. Promoted to associate professor in 2022. He has been engaged in teaching and scientific research in quantum optical instruments, optoelectronic devices, micro and nano processing and measurement, unmanned vehicle laser radar and other fields. His main research directions include ultrafast laser micro and nano processing, ultrafast laser processing monitoring integration, limit photoelectric detection and single photon imaging. He presided over two provincial and ministerial level projects, including the national Youth Talent Plan project and the major scientific and technological innovation project of Shandong Province. He has published more than 30 SCI papers in Nano Letter, ACS Nano, Small and other international and domestic journals, and has been cited by SCI more than 1400 times. Received the Australian Braja Warrior of the Year Award for a major breakthrough in Lidar products. The main course is introduction to nanomicroscopy. There are 3 doctoral students and 5 master students.
Xu Kemi, female, born in Gongzhuling City, Jilin Province in January 1984, Ph.D., studied in Australia from 2014 to 2020, won the Postdoctoral President Scholarship of Global Talent Program of University of New South Wales in Australia in 2014, joined Beijing Institute of Technology in 2020, was hired as a doctoral supervisor in 2020, and was selected as a national Young Talent Program in 2022. Promoted to associate professor in 2022. He has been engaged in teaching and scientific research in quantum optical instruments, optoelectronic devices, micro and nano processing and measurement, unmanned vehicle laser radar and other fields. His main research directions include ultrafast laser micro and nano processing, ultrafast laser processing monitoring integration, limit photoelectric detection and single photon imaging. He presided over two provincial and ministerial level projects, including the national Youth Talent Plan project and the major scientific and technological innovation project of Shandong Province. He has published more than 30 SCI papers in Nano Letter, ACS Nano, Small and other international and domestic journals, and has been cited by SCI more than 1400 times. Received the Australian Braja Warrior of the Year Award for a major breakthrough in Lidar products. The main course is introduction to nanomicroscopy. There are 3 doctoral students and 5 master students.
1. Quantum optical instruments;
2. Integration of ultrafast laser processing and testing;
3. Optical precision measurement;
4. Single photon imaging;
(1) 2010-09 to 2013-06, Physical Electronics, Jilin University, Ph. D.
(2) 2008-09 to 2010-06, Microelectronics and Solid-State Electronics, Jilin University, Master
(3) 2003-09 to 2007-06, Jilin University, Electronic Science and Technology, B.S.
(1) From 2007-08 to 2008-07, volunteer teacher of "College Students Volunteer Service West Program" of the League Central Committee;
(2) 2014-03 to 2018-04, Postdoctoral Researcher, University of New South Wales, Australia;
(3) Optical Engineer, BARAJA, Australia, 2018-04 to 2020-09;
(4) 2020-11.- Till now, Teacher, School of Optoelectronics, Beijing Institute of Technology.
【论文】
(1) In- situ high-precision surface topographic and Raman mapping by divided-aperture differential confocal Raman microscopy. Applied Surface Science, Vol.546, p149061, 2021.4.
(2) Ultrashallow Junction Electrodes in Low-Loss Silicon Microring Resonators, Phys. Rev. Applied 15, 044014 (2021)
(3) Light-Driven Magnetic Encoding for Hybrid Magnetic Micromachines, Nano Letters, Vol.21, No.4, p1628, 2021.2.
(4) Competition between subwavelength and deep- subwavelength structures ablated by ultrashort laser pulses, Optica, Vol.4, No.6, p637, 2017.6.
(5) Surface-plasmon-mediated programmable optical nanofabrication of an oriented silver nanoplate, ACS Nano, Vol.8, No.7, p 6682, 2014.6.
(6) Flexible nanowiring of metal on nonplanar substrates by femtosecond-laser-induced electroless plating, Small, Vol.6, No.16, p1762, 2010.8.
(7) Localized flexible integration of high-efficiency surface enhanced Raman scattering (SERS) monitors into microfluidic channels, Lab On a Chip, Vol.11, No.19, p3347, 2011.8.
(8) Fabrication and multifunction integration of microfluidic chips by femtosecond laser direct writing, Lab on a Chip, Vol.13, No.9, p1677, 2013.2.
(9) Laser patterning of conductive gold micronanostructures from nanodots, Nanoscale, Vol.4, No.22, p6955, 2012.8.
(10) On-chip fabrication of silver microflower arrays as a catalytic microreactor for allowing in-situ SERS monitoring, Chemical Communications, Vol.48, No.11, p1680, 2011.12.
(11) Silver coated rose petal: a green, facile, low-cost and sustainable fabrication of SERS substrate with unique superhydrophobicity and high efficiency, Advanced Optical Materials, Vol.1, No.1, p56, 2013.1.
(12) On-chip catalytic microreactors for modern catalysis research, ChemCatChem, Vol.5, No.8, p2091, 2013.8.
(13) Programmable assembly of CdTe quantum dots into microstructures by femtosecond laser direct writing, Journal of Materials Chemistry C, Vol.1, No.31, p4699, 2013.6.
(14) Fabrication of microelectrodes based on precursor doped with metal seeds by femtosecond laser direct writing, Optics Letters, Vol.39, No.3, p434, 2014.2.
(15) A SERS-active microfluidic device with tunable surface plasmon resonances, Electrophoresis, Vol.32, No.23, p3378, 2011.11.
In 2015, UN member states agreed to 17 global Sustainable Development Goals (SDGs) to end poverty, protect the planet and ensure prosperity for all. This person’s work contributes towards the following SDG(s):