基本信息
views: 310
Career Trajectory
Bio
Our group is working on quantum photonics and quantum materials based on solid state. In particular, the research in these two systems focuses on wide-bandgap materials and two-dimensional materials.
The target of wide-bandgap material research is to use the properties of color centers in these materials to perform quantum information applications, especially in diamond, silicon carbide (SiC) and gallium nitride (GaN). (1) The spin information and photon information in these systems, especially the possibility of spin-photon interface and chip integration, make them attractive for quantum network constructions. (2) The robust spin coherence makes them suitable candidates for quantum computing and quantum sensing.
On the two-dimensional material aspect, here are some examples. (1) The spin and valley degree of freedom in 2D materials not only provide addition knobs towards “green electronics” to reduce energy consumptions, as compared to charge degree of freedom; they also provide promising platform for studying emerging quantum phenomenon such as quantum anomalous hall effect. (2) In addition, Moiré system in twisted structure provides flexible system to study quantum many-body problems, especially the physics interaction between Moire trapped excitons and quantum well. (3) Long lifetime dipolar excitons might lead to BEC state for these quasiparticles. (4) 2D magnetism provides an interesting platform for designed spintronics and coupling between quantum systems in different dimensions.
The target of wide-bandgap material research is to use the properties of color centers in these materials to perform quantum information applications, especially in diamond, silicon carbide (SiC) and gallium nitride (GaN). (1) The spin information and photon information in these systems, especially the possibility of spin-photon interface and chip integration, make them attractive for quantum network constructions. (2) The robust spin coherence makes them suitable candidates for quantum computing and quantum sensing.
On the two-dimensional material aspect, here are some examples. (1) The spin and valley degree of freedom in 2D materials not only provide addition knobs towards “green electronics” to reduce energy consumptions, as compared to charge degree of freedom; they also provide promising platform for studying emerging quantum phenomenon such as quantum anomalous hall effect. (2) In addition, Moiré system in twisted structure provides flexible system to study quantum many-body problems, especially the physics interaction between Moire trapped excitons and quantum well. (3) Long lifetime dipolar excitons might lead to BEC state for these quasiparticles. (4) 2D magnetism provides an interesting platform for designed spintronics and coupling between quantum systems in different dimensions.
Research Interests
Papers共 249 篇Author StatisticsCo-AuthorSimilar Experts
By YearBy Citation主题筛选期刊级别筛选合作者筛选合作机构筛选
时间
引用量
主题
期刊级别
合作者
合作机构
crossref(2024)
Reports on progress in physics Physical Society (Great Britain) (2024)
NANO LETTERSno. 29 (2024): 8795-8800
Yi Yu, Junyu Ge, Manlin Luo, In Cheol Seo,Youngmin Kim, John J. H. Eng, Kunze Lu,Tian-Ran Wei,Weibo Gao,Hong Li,Donguk Nam
arxiv(2024)
Cited0Views0Bibtex
0
0
Shu An,Dmitry Kalashnikov, Wenqiao Shi,Zackaria Mahfoud, Ah Bian Chew,Yan Liu,Jing Wu,Di Zhu,Weibo Gao,Cheng-Wei Qiu,Victor Leong,Zhaogang Dong
arxiv(2024)
Cited0Views0Bibtex
0
0
Hao Jiang, Yinzhu Chen, Wenyu Guo, Yan Zhang,Rigui Zhou,Mile Gu,Fan Zhong,Zhenhua Ni,Junpeng Lu,Cheng-Wei Qiu,Weibo Gao
Nature communicationsno. 1 (2024): 8347-8347
Zaixin Wei,Yao Liu, Yan Zhang, Kallioniemi Leevi Aleksanteri, Xiangru Qi,Zidong Zhang,Zhongyang Wang,Weibo Gao,Runhua Fan
NATIONAL SCIENCE REVIEWno. 6 (2024)
PHYSICAL CHEMISTRY CHEMICAL PHYSICSno. 2 (2024): 895-902
Load More
Author Statistics
#Papers: 249
#Citation: 9330
H-Index: 48
G-Index: 95
Sociability: 7
Diversity: 3
Activity: 229
Co-Author
Co-Institution
D-Core
- 合作者
- 学生
- 导师
Data Disclaimer
The page data are from open Internet sources, cooperative publishers and automatic analysis results through AI technology. We do not make any commitments and guarantees for the validity, accuracy, correctness, reliability, completeness and timeliness of the page data. If you have any questions, please contact us by email: report@aminer.cn