Dr. Liu Xuwen holds a Ph.D. in engineering and serves as an associate professor and master's supervisor. He has been recognized under the High-Level Talent Program and the Youth Science and Technology Talent Support Project of Hubei Province. Dr. Liu is a associate professor and core researcher at the National Key Laboratory of Precision Blasting at Jianghan University and holds a senior engineering technician qualification (Level B). He obtained his doctorate from Nanjing University of Science and Technology, where he focused on advanced methods for developing innovative materials in collaboration with the French National Centre for Scientific Research at the System Analysis and Architecture Laboratory, under the supervision of Professor Carole Rossi.
His research has involved the preparation, performance, and application of innovative materials, as well as examining the interactions between lasers and materials. He has extensive experience in developing safety materials, transient testing technologies for combustion processes, advanced photosensitive materials, energy release characteristics of composite materials, and ignition mechanisms.
In recent years, Dr. Liu has published over twenty papers as the first or corresponding author, including 13 indexed by SCI and 2 by EI. As a project leader, he has managed initiatives funded by the National Natural Science Foundation, the Ministry of Education's Youth Talent Program (the only one in Hubei Province for 2023), and various collaborative projects, including one with the National University of Kazakhstan and key research and development projects in partnership with the French National Centre for Scientific Research. He has also led numerous scientific research projects and educational reform initiatives and actively participated in interdisciplinary community outreach efforts. Dr. Liu has been granted ten national invention patents.
Publication:
[1] Liu X, Hu Y, Yang C, et al. Recovering copper ions from wastewater with chitosan to synthesize lead-free primary explosives[J]. Journal of Alloys and Compounds, 2022, 914: 165252.
[2] Liu X, Hu Y, Chen B, et al. Fabrication and properties of MEMS compatible energetic arrays based on carbon-based copper azide[J]. Applied Surface Science, 2022, 577: 150643.
[3] Liu X, Hu Y, Hu J, et al. Template synthesis of copper azide primary explosive through Cu2O@HKUST-1 core-shell composite prepared by “bottle around ship” method[J]. Defence Technology, 2023, 25: 99-111.
[4] Li J#, Liu X#, Huang Q, et al. A Novel Nano-Thermite System with BiOF as Fluorine-Containing Oxidant for Enhanced Energy Release Performance[J]. Chemical Engineering Journal, 2023, 468: 143591.
[5] Li J, Liu X*, Xie Q, et al. Cryogel-Templated Fabrication of n-Al/PVDF Superhydrophobic Energetic Films with Exceptional Underwater Ignition Performance[J]. Molecules, 2022, 27(20): 6911.
[6] Li J#, Liu X#, Xie Q, et al. Effect of Perchlorate on Combustion Properties of Directly-written Al/PVDF Composites[J]. Fire, 2023, 6(3), 106.
[7] Xian M, Zhao K, Liu X*, et al. Theoretical analysis and numerical simulation of the motion of RDX deflagration-driven flyer plate based on laser-initiated micro-pyrotechnic devices[J]. Micromachines, 2023, 14(5): 917.
[8] Liu P, Lei F Q, Yu J, Liu X W*. Effect of tetraammine copper nitrate on reaction characteristics of n-Al/MoO3 nano-thermite system[J]. Explosive Materials, 2024, 53(5): 44-53. (in Chinese)
[9] Li J W, Liu X W, Yin G Y, et al. Research progress on regulating reaction activity of metallic fuels with fluorine-containing compounds[J]. Chinese Journal of Explosives & Propellants, 2024, 47(11): 955-977. (in Chinese)
[10] Liu X, Li J*, Feng S, et al. Pioneering Insights into the Reaction Kinetics of Metastable Intermolecular Composites Based on Metal Fluorides: Virtually Nonexistent Condensed Phase Combustion Products and Ultra-Efficient Reactivity[J]. Advanced Science, Under Review.
[11] Li J, Liu X*, Yin G, et al. Reengineering Nano-Thermite Energy Dynamics through Molecular Fluorination: Pioneering Applications in Transient Electronics[J]. Chemical Engineering Journal, Under Review.
[12] Li J, Liu X*, Ming Z, et al. Two-dimensional design of reaction components endows metastable intermolecular complexes with characteristic sensitivity and enhanced energy release performance[J]. Chemical Engineering Journal, Under Review.
[13] Xie Q, Liu X, Zhang Z, et al. Investigation of mechanical and electronic properties of a novel quaternary transition-metal nitride Ti0.25W0.25V0.25Ta0.25N[J]. Materials Chemistry and Physics, 2023, 310: 128467.
[14] Xie Q, Yao Y, Liu X, et al. Theoretical study on mechanical and electronic properties of ternary diborides Sc0.5V0.5B2, Sc0.5Nb0.5B2 and Sc0.5Ta0.5B2[J]. Materials Today Communications, 2023, 35: 105760.
[15] Zhang Z, Huo K, Yan T, Liu X, et al. Mechanistic insights into the selective photocatalytic degradation of dyes over TiO2/ZSM-11[J]. Frontiers of Environmental Science & Engineering, 2023, 17(8): 101.
[16] Liu X, Hu Y, Li T, et al. An energetic composite formed of wrinkled rGO sheets wrapped around copper azide nanowires with higher electrostatic safety as a green primary explosive[J]. RSC Advances, 2020, 10(51): 30700-30706.
[17] Liu X, Hu Y, Wei H, et al. Energetic films realized by encapsulating copper azide in silicon-based carbon nanotube arrays with higher electrostatic safety[J]. Micromachines, 2020, 11(6): 575.
[18] Liu X W, Hu Y, Ye Y H, Shen R Q. Research progress on copper azide energetic materials[J]. Chinese Journal of Energetic Materials, 2021, 29(5): 444-459. (in Chinese)
[19] Liu X, Li T, Hu Y, et al. Copper azide nanowires@rgo energetic composite with low electrostatic sensitivity[C]//Journal of Physics: Conference Series. IOP Publishing, 2020, 1507(2): 022004.
[20] Sevely F, Liu X, Wu T, et al. Effect of Process Parameters on the Properties of Direct Written Gas Generating Reactive Layers[J]. ACS Applied Polymer Materials, 2021, 3(8): 3972-3980.
[21] Wei H, Liu X W, Hu Y, et al. Preparation and characterization of silicon-based Cu(N3)2@CNTs composite energetic films[J]. Chinese Journal of Energetic Materials, 2020, 28(6): 525-531. (in Chinese)
[22] Shi C K, Xu X N, Dong C, Liu X W, Hu Y. Preparation and characterization of carbon nanotube composite energetic materials embedded with copper azide[J]. Explosive Materials, 2019(5): 19-23. (in Chinese)
[23] Yang C, Hu Y, Zeng H, Liu X, Ye Y, & Shen, R. (2022, May). Fabrication of HKUST-1 Based Ink for Direct Writing of Precursors of Primary Explosives. In 2021 International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials (pp. 323-339). Singapore: Springer Nature Singapore.
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