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Copyright@Beijing University of Chemical Technology Address: 15 Beisanhuan East Road, Chaoyang District, Beijing, China Zip code:100029 Email:news@buct.edu.cn |
IntroductionProf. Xiaodong Wang is a professor of Beijing University of Chemical Technology and a fellow of State Key Laboratory of Organic–Inorganic Composites, China. He obtained the Ph.D. degree from the same university in Polymer Science and Engineering and was a postdoctoral fellow at DOOSAN Corporation Electro-Materials in South Korea from 1996 to 1998. He was a visiting professor at Pierre and Marie Curie University in France from 2011 to 2012. His research interest is focused on polymer compounding and processing, organic–inorganic nanocomposites, microencapsulation of phase change materials, thermal energy storage, and thermal management. He is the principal author of over 200 publications in international scholarly journals. Educational Background Ph.D., Polymer Science, Beijing University of Chemical Technology, June 1996 M.Sc., Polymer Science, Beijing University of Chemical Technology, June 1994 B.Sc., Polymer Science, Beijing Institute of Chemical Technology, June 1990 Career Experience2003 – present: Full Professor, School of Materials Science and Engineering, Beijing University of Chemical Technology 2010 –Dec. 2011: Visiting Professor, The University Pierre et Marie Curie, Paris, France 2002 – Dec. 2002: Senior Researcher, Institute of Electronic Materials, KOLON Industry Inc., South Korea 1998 – Sept. 2001: Associate Professor, School of Materials Science and Engineering, Beijing University of Chemical Technology 1996 – Sept. 1998: Post-doctoral Researcher, R & D Center, DOOSAN Corporation Electro-Materials BG, South Korea EducationWork ExperienceSocial PositionSocial ActivitiesResearch(1) Phase-change materials and their composites for multipurpose applications. (2) Microencapsulation of phase-change materials for thermal enerngy storage and thermal management. (3) Polymer physics, polymer compounding and processing, inorganic-organic composites. (4) Molecular design and synthesis of functional polymers. (5) Preparation and application of electronic materials, especially, epoxy/glass fabric composites for electronics application, dry film photo-resist, and solder mask ink. TeachingPostgraduatesFundingVertical ProjectHorizontal ProjectPublications[1] H. Zhang, S. Zhou, H. Liu*, Z. Qian*, X. Wang*, All-weather solar-powered desalination and synchronous Cs+ extraction for salt-lake water enabled by crown-ether-decorated phase-change microcapsules, Advanced Functional Materials, 2024, 34, 2408269.
[3] J. Jing, H. Liu*, X. Wang*, Long-term infrared stealth by sandwich-like phase-change composites at elevated temperatures via synergistic emissivity and thermal regulation, Advanced Functional Materials, 2024, 34, 2309269.
[4] T. Shi, H. Liu*, X. Wang*, Unidirectionally structured magnetic phase-change composite based on carbonized polyimide/Kevlar nanofiber complex aerogel for boosting solar-thermo-electric energy conversion, ACS Applied Materials & Interfaces, 2024, 16: 10180−10195.
[5] X. Gao, T. Shi, L. Zu, H. Lian, X. Cui, X. Wang*, Highly stable polyaniline-based cathode material enabled by phosphorene for zinc-ion batteries with superior specific capacity and cycle life, ACS Applied Materials & Interfaces, 2024, 16: 24781−24795.
[6] Y. Zhou, W. Liu, S. Zhang, H. Lian*, Z. Wu*, X. Wang*, Eco-friendly flame-retardant phase-change composite films based on polyphosphazene/phosphorene hybrid foam and paraffin wax for light/heat-dual-actuated shape memory, ACS Applied Materials & Interfaces, 2024, 16: 7754−7767.
[7] H. Liu, J. Jing, J. Liu, X. Wang*, Sugar alcohol-based phase change materials for thermal energy storage: Optimization design and applications, Renewable and Sustainable Energy Reviews, 2024, 199: 114528.
[9] Z. Zheng, H. Liu*, X. Wang*, Double-layered hydrogels based on phase change material and pen ink for continuous and efficient solar-driven seawater desalination, Desalination, 2024, 574: 117276.
[10] T. Shi, H. Liu*, X. Wang*, Multi-stimuli-responsive shape memory flexible composites based on magnetic melamine/polydopamine/phosphorene complex foams and polyethylene glycol, Composites Part A, 2024, 181: 108117.
[11] F. Sun, G. Tian*, H. Liu, D. Wu, X. Wang*, Solar photothermal self-deicing composite films based on fluorinated polyimide and phosphorene nanoflakes for passive anti-icing of photovoltaic panels, Materials Today Sustainability, 2024, 26: 100794.
[12] H. Wan, S. Lia, Y. Wang, Z. Chen, J. He, C. Li, G. Liu, J. Liu*, X. Wang*, T. P. Russelle*, L. Zhang*. All-polymer nanocomposites having superior strength, toughness and ultralow energy dissipation, Nano Energy, 2023, 118: 108925.
[13] S. Chen, Z. Zheng, H. Liu, X. Wang*, Highly efficient, antibacterial, and salt-resistant strategy based on carbon black/chitosan-decorated phase-change microcapsules for solar-powered seawater desalination, ACS Applied Materials & Interfaces, 2023, 15: 16640−16653.
[14] H. Liu, D. Tian, Z. Zheng, X. Wang*, Z. Qian, MXene-decorated magnetic phase-change microcapsules for solar-driven continuous seawater desalination with easy salt accumulation elimination, Chemical Engineering Journal, 2023, 458: 141395.
[15] W. Li, Z. Zheng, H. Liu*, X. Wang*, A solar-driven seawater desalination and electricity generation integrating system based on carbon black-decorated magnetic phase-change composites, Desalination, 2023, 562: 116713.
[16] M, Zhang, K. Sun, Z. Zheng, H. Liu*, X. Wang*, Development of MXene-decorated sodium alginate/SiO2@n-docosane hierarchical phase-change microcapsules for solar-driven sustainable seawater desalination, Desalination, 2023, 550: 116380.
[17] X. Tian, H. Liu, H. Liu*, X. Wang*, Flexible phase-change composite films for infrared thermal camouflage and photothermal energy storage, Journal of Energy Storage, 2023, 73: 109203.
[18] M. Chen, H. Liu*, H. Zhang, X. Wang*, Development of BaSO4@n-eicosane phase-change microcapsules with high corrosion resistance for thermal regulation application in architectural coatings, Journal of Energy Storage, 2023, 57: 106232.
[19] G. Liao, H. Liu, X. Wang*, More accurate and more efficient: Penicillinase-immobilized phase-change microcapsules for detection and removal of penicillins under microenvironmental thermal management, Journal of Environmental Chemical Engineering, 2023, 11: 109148.
[20] M, Zhang, H. Liu X. Wang*, Cholesterol oxidase-immobilized MXene/sodium alginate/silica@n-docosane hierarchical microcapsules for ultrasensitive electrochemical biosensing detection of cholesterol, Journal of Materials Chemistry B, 2023, 11, 1506.
[21] H. Shen, H. Liu, X. Wang*, Surface construction of catalase-immobilized Au/PEDOT nanocomposite on phase-change microcapsules for enhancing electrochemical biosensing detection of hydrogen peroxide, Applied Surface Science, 2023, 612: 155816.
[22] H. Shen, Z. Zheng, H. Liu, X. Wang*, A solar-powered interfacial evaporation system based on MoS2-decorated magnetic phase-change microcapsules for sustainable seawater desalination, Journal of Materials Chemistry A, 2022, 10, 25509.
[23] Z. Zheng, W. Li, H. Liu, X. Wang*, Sustainable interfacial evaporation system based on hierarchical MXene/polydopamine/magnetic phase-change microcapsule composites for solar-driven seawater desalination, ACS Applied Materials & Interfaces, 2022, 14: 50966−50981. [24] X. Tian, H. Liu, H. Liu, X. Wang* Immobilizing diamine oxidase on electroactive phase-change microcapsules to construct thermoregulatory smart biosensor for enhancing detection of histamine in foods, Food Chemistry, 2022, 397: 133759.
[25] Z. Zheng, H. Liu*, D. Wu, X. Wang*, Polyimide/MXene hybrid aerogel-based phase-change composites for solar-driven seawater desalination, Chemical Engineering Journal, 2022, 440: 135862.
[27] Z. Sun, H. Liu*, X. Wang*, Hierarchically nanostructured Co(OH)2/MXene/SiO2/n-docosane phase-change composites for enhancement of supercapacitor performance under in-situ thermal management, Composites Part B, 2022, 242: 110112.
[29] Z. Sun, T. Shi, Y. Wang, J. Li, H. Liu*, X. Wang*, Hierarchical microencapsulation of phase change material with carbon-nanotubes/polydopamine/silica shell for synergistic enhancement of solar photothermal conversion and storage, Solar Energy Materials & Solar Cells, 2022, 236: 111539. [30] T. Shi, Z. Zheng, H. Liu*, D. Wu, X. Wang*, Configuration of multifunctional polyimide/graphene/Fe3O4 hybrid aerogel-based phase-change composite films for electromagnetic and infrared bi-stealth, Nanomaterials, 2021, 11: 3038. [31] H. Liu, Z. Qian*, Q. Wang, D. Wu, X. Wang*, Development of renewable biomass-derived carbonaceous aerogel/mannitol phase-change composites for high thermal-energy-release efficiency and shape stabilization, ACS Applied Energy Materials, 2021, 4: 1714−1730 [32] H. Liu, Z. Zheng, Z. Qian*, Q. Wang, D. Wu, X. Wang*, Lamellar-structured phase change composites based on biomass-derived carbonaceous sheets and sodium acetate trihydrate for high-efficient solar photothermal energy harvest, Solar Energy Materials & Solar Cells 2021, 229: 111140 [33] J. Li, J. Yu, [34] H. Liu, X. Tian, M. Ouyang, X. Wang, D. Wu, X. Wang*, Microencapsulating n-docosane phase change material into CaCO3/Fe3O4 composites for high-efficient utilization of solar photothermal energy, Renewable Energy, 2021, 179: 47–64. [35] Z. Sun, L. Zhao, H. Wan, H. Liu*, D. Wu, X. Wang*, Nanoflaky nickel-hydroxide-decorated phase-change microcapsules as smart electrode materials with thermal self-regulation function for supercapacitor application, Renewable Energy, 2021, 174: 557–572. [36] Z. Sun, Z. Han, H. Liu*, D. Wu, X. Wang*, Construction of polyaniline/carbon nanotubes-functionalized phase-change microcapsules for thermal management application of supercapacitors, Chemical Engineering Journal, 2020, 396: 125317. [37] L. Zhao, Z. Sun, H. Wan, H. Liu*, D. Wu, X. Wang*, X. Cui, A novel self-thermoregulatory electrode material based on phosphorene-decorated phase-change microcapsules for supercapacitors, Electrochimica Acta, 2020, 354: 136718. [38] Y. Zhang, H. Liu, J. Niu, X. Wang*, D. Wu, Development of reversible and durable thermochromic phase-change microcapsules for real-time indication of thermal energy storage and management, Applied Energy, 2020, 264: 114729. [39] J. Niu, H. Liu, X. Wang*, Dezhen Wu, Molecularly imprinted phase-change microcapsule system for bifunctional applications in waste heat recovery and targeted pollutant removal, ACS Applied Materials & Interfaces, 2019, 11: 37644−37664. [40] K. Sun, H. Liu, X. Wang*, D. Wu, Innovative design of superhydrophobic thermal energy-storage materials by microencapsulation of n-docosane with nanostructured ZnO/SiO2 shell, Applied Energy, 2019, 237: 549–565. [41] H. Wan, K. Gao, S. Li, L. Zhang, X. Wu*, X. Wang*, J. Liu*, Chemical bond scission and physical slippage in the mullins effect and fatigue behavior of elastomers, Macromolecules, 2019, 52: 4209−4221. [42] C. Wu, X. Wang* J. Zhang, J. Cheng, L. Shi*, Microencapsulation and surface functionalization of ammonium polyphosphate via in-situ polymerization and thiol-ene photograted reaction for application in flame-retardant natural rubber, Industrial & Engineering Chemistry Research, 2019, 58: 17346−17358. [43] J. Li, Y. Wang, X. Wang*, D. Wu*, Crystalline characteristics, mechanical properties, thermal degradation kinetics and hydration behavior of biodegradable fibers melt-spun from polyoxymethylene/poly(l-lactic acid) blends, Polymers, 2019, 11: 1516. [44] J. Li, Y. Wang, X. Wang*, D. Wu*, Development of polyoxymethylene/polylactide blends for a potentially biodegradable material: crystallization kinetics, lifespan prediction, and enzymatic degradation behavior, Polymers, 2019, 11: 1753. [45] Q. Xu, H. Liu, X. Wang*, D. Wu, Smart design and construction of nanoflake-like MnO2/SiO2 hierarchical microcapsules containing phase change material for in-situ thermal management of supercapacitors, Energy Conversion and Management, 2018, 164: 311–328. [46] H. Liu, X. Wang*, D. Wu, Tailoring of bifunctional microencapsulated phase change materials with CdS/SiO2 double-layered shell for solar photocatalysis and solar thermal energy storage, Applied Thermal Engineering, 2018, 134: 603–614. [47] L. Zhang, E. Han, Y. Wu, X. Wang*, D. Wu, Surface decoration of short-cut polyimide fibers with multi-walled carbon nanotubes and their application for reinforcement of lightweight PC/ABS composites, Applied Surface Science, 2018, 442: 124–137. AwardsPatentHonor RewardAdmissions Information |