Junjie Li is Professor of Xinjiang Technical Institute of Physics & Chemistry, CAS. He received his Ph.D. from East China Normal University (2015). After postdoctoral works at International Iberian Nanotechnology Laboratory (2016-2018) and école Polytechnique Fédérale de Lausanne (2019), he worked as a full professor at Xinjiang Technical Institute of Physics & Chemistry, CAS. His current research interests include the study of crystal nucleation and growth dynamics, single crystal growth, structural characterization, exploration of new optical-electronic functional materials.
Research Interests
1.The exploration of new optical-electronic functional materials;
2. In-situ investigation of crystal nucleation and growth;
3. The growth of crystal;
Achievements
Junjie Li has published more than 70 papers and 5 review articles in major international journals including Chemical Reviews, Advanced Materials, Angewandte Chemie International Edition, Journal of the American Chemical Society, Nature Communications, Acs Nano, and etc. In addition he has one book chapter “Advanced Electron Microscopic Techniques towards the Understanding of Metal Nanoparticles and Clusters” Springer (2018). Several of his articles have made it to the cover page of journals. He is the member of editorial board of Nano Energy Research. He served as the guest editor for a special issue of the Journal of Nano Materials: An Overview of the Recent Advances in Advanced Electron Microscopy Imaging, Spectroscopy and their Related Applications. He has participated in three National projects and five region projects. In addition he is an acting referee for various ACS, RSC and Elsevier journals among others. He also holds 3 joint patents.
Main Honor:
Junjie Li was awarded by the First Prize of Xinjiang’s Natural Science Award in 2020.
Representative Publications:
1. Junjie Li*, Francis Leonard Deepak*, In-Situ Kinetic Observations on Crystal Nucleation and Growth. Chemical Reviews, 2022, Accept.
2. Peng Wang,? Yu Chu,? Abudukadi Tudi,? Congwei Xie, Zhihua Yang, Shilie Pan,* Junjie Li,* The Combination of Structure Prediction and Experiment for the Exploration of Alkali-Earth Metal-Contained Chalcopyrite-Like IR Nonlinear Optical Material. Advanced Science, 2022, 9, 2106120.
3. Ailijiang Abudurasuli,? Junben Huang,? Peng Wang, Zhihua Yang, Shilie Pan,* Junjie Li,* Li4MgGe2S7: The First Alkali and Alkaline-Earth Diamond-Like Infrared Nonlinear Optical Material with Exceptional Large Band Gap. Angewandte Chemie-International Edition, 2021,60, 24131-24136.
4. Yu Chu, ? Peng Wang, ? Hao Zeng, Shichao Cheng, Xin Su, Zhihua Yang, Junjie Li,* Shilie Pan,* Hg3P2S8: A new promising infrared nonlinear optical material with a large second-harmonic generation and a high laser-induced damage yhreshold. Chemistry of Materials., 2021, 33, 6514–6521.
5. Junjie Li*, Francis Leonard Deepak*, Atomic-Scale Dynamic Observation Reveals Temperature-Dependent Multistep Nucleation Pathways in Crystallization. Nanoscale Horizons, 2019, 4, 1302-1309.
6. Qiang Li, Bin Wei, Yue Li, Junyuan Xu*, Junjie Li*, Lifeng Liu, Leonard Francis, Large-Scale Fabrication of Hollow Pt3Al Nanoboxes and Their Electrocatalytic Performance for Hydrogen Evolution Reaction. ACS Sustainable Chemistry & Engineering, 2019, 7, 9842-9847.
7. Junjie Li, Zhongchang Wang, Yunping Li and Francis Leonard Deepak*, In situ Atomic-Scale Observation of Kinetic Pathways of sublimation in Silver Nanoparticles. Advanced Science, 2018, 6, 1802131.
8. Junjie Li, Zhongchang Wang, and Francis Leonard Deepak*, Direct Atomic-Scale Observation of Intermediate Pathways of Melting and Crystallization in Supported Bi-Nanoparticles. The Journal of Physical Chemistry Letters,2018, 9, 961–969.
Junjie Li, Jiangchun, Chen, Hua Wang, Na Chen, Zhongchang Wang, Lin Guo and Francis Leonard Deepak*, In situ Atomic-Scale Study of Particle Mediated Nucleation and Growth in Amorphous Bi to Nanocrystal Phase Transformation. Advanced Science,1. 2018, 5, 1700992.
Li, Junjie, Zhongchang Wang, and Francis Leonard Deepak*. In-Situ Atomic-Scale Observation of Droplet Coalescence Driven Nucleation and Growth at Liquid/Solid Interfaces. Acs Nano, 2017, 11, 5590-5597.