Name: Fen Qiao
Title: Full Professor
E-mail:fqiao@ujs.edu.cn

Working Experience

June 2020 - Present  Jiangsu University, Professor
September 2015-September 2016 National University of Singapore, Visiting academic

Education Background
● Doctor of Engineering (March.2007 – April. 2010)
-Major: microelectronics and solid state electronics,Dalian University of Technology, China
● Doctor of Engineering (Sep.2008 - Sep.2009)
-Major: Material Science Engineering, Nanyang Technological University, Singapore
● Postdocor Researcher (April.2010 - April.2012)
Major: Nanochemistry, IIT Institute, Italy

Research Interests
● Hydrogen Energy Production
● Supercapacitors
● DFT Simulation

Research Techniques and Skills
● Experimental techniques: Hydrogen Evolution Reaction System
● DFT simulation: The first principle

Projects
● National Natural Science Foundation General Project, 2024-2027
● National Natural Science Foundation General Project, 2019-2023
● National Natural Science Foundation of China Youth Project, 2015-2017
● National Fund for Returned Overseas Students, 2013-2015
● National Special Fund for Postdoctoral Fellowship, 2016-2018
● Postdoctoral Fund of Jiangsu Province,2018-2020
● China Postdoctoral Science Foundation, 2015-2017
● Postdoctoral Fund of Jiangsu Province,2015-2017
● Jiangsu University Young Backbone Teacher Training Project,2014-2018
● Jiangsu University Senior Talent Start-up Fund,2013-2015
● Enterprise Entrusts Horizontal Projects, 2018-2020

Publications (in the last three years)
[1]F.Qiao, W. Liu, et al. Hydrogen production performance and theoretical mechanism analysis of chain-like ZnO/ZnS heterojunction. International Journal of Hydrogen Energy, 2023.
[2]W. Liu, F.Qiao, et al. Cobalt disulfide/carbon nanofibers with mesoporous heterostructure and excellent hydrophilicity for high energy density asymmetric supercapacitor. Nano Research, 2023.
[3]D.Khalafallah, F.Qiao, et al. Heterostructured transition metal chalcogenides with strategic heterointerfaces for electrochemical energy conversion/Storage. Coordination Chemistry Reviews, 2023.
[4]D.Jin, F.Qiao, et al. Cu/Mo 2 C Synthesized through Anderson-type Polyoxometalates Modulate Interfacial Water Structure to Achieve Hydrogen Evolution at High Current Density. Nano Research, 2023.
[5]D.Jin, F.Qiao, et al. Progress in electrocatalytic hydrogen evolution of transition metal alloys: synthesis, structure, and mechanism analysis. Nanoscale, 2023.
[6]F.Qiao, S.Qian, et al. Cu 2 O/Cu 2 S microstructure regulation towards high efficiency photocatalytic hydrogen production and its theoretical mechanism analysis. CrystEngComm, 2023.
[7]F.Qiao, K.Sun, et al. Design strategies of ZnO heterojunction arrays towards effective photovoltaic applications. Battery Energy, 2022.
[8]F.Qiao, K.Sun, W.Liu, et al. Bandgap modulation of ZnO/ZnS heterostructures through ion exchange and their efficient transport properties. Vacuum, 2022.
[9]F.Qiao, et al.Recent progress of transparent conductive electrodes in the construction of efficient flexible organic solar cells, International Journal of Energy Research, 2021.
[10]F.Qiao, K.Sun, et al.Bandgap modulation of ZnO/ZnS heterostructures through ion exchange and their efficient transport properties,Vacuum,2021.
[11]F.Qiao, Y.Xi, et al. Ligand engineering of colloid quantum dots and their application in all-inorganic tandem solar cells,Journal of Energy Chemistry,2020.       
[12]F. Qiao, Y. Xie,Strategies for enhancing conductivity of colloidal nanocrystals and their photoelectronic applications,Journal of Energy Chemistry,2020.
[13]F. Qiao, Y.Xie, et al.,Light trapping structures and plasmons synergistically enhance the photovoltaic performance of full-spectrum solar cells,Nanoscale,2020, .   
[14]F.Qiao, Q. Liang, et al.,Fabrication of multi-crystalline silicon pyramid structure and improvement in its photovoltaic performance,Journal of Materials Science, 2020. 
[15]F.Qiao, Z. Chen, et al.Construction of microsphere-shaped ZnSe-AgZnInS and its charge transport property,Journal of Materials Research and Technology, 2020.
[16]Z.Chen#, F.Qiao#*, et al.,Influence of cleaning treatment on structure, optical and electrical properties of Ag/ZnSe microspheres prepared by silver mirror reaction,Vacuum, 2020.
[17]F. Qiao, R.Kang, et al., Tunability in the optical and electronic properties of ZnSe microspheres via Ag and Mn doping, ACS Omega, 2019.
[18]F. Qiao, Q.Liang, et al., Fabrication of multi-crystalline silicon pyramid structure and improvement in its photovoltaic performance, Journal of Materials Science,2020.
[19]F. Qiao, Q. Liang,et al., Two-step preparation of ZnO/ZnSe heterostructure with  remarkable photocatalytic activity by ultrasonic and hydrothermal approach, Journal of Electronic Materials, 2019,48(7):4418-4423.
[20]F.Qiao, Q.Liang, et al., A facile approach of fabricating various ZnO microstructures via electrochemical deposition, Journal of Electronic Materials, 2019.
[21]F. Qiao, Q. Liang, et al., Tunable Formation of ZnSe to ZnO due to a Controlled  Phase Transition Driven by Hydrazine and Sodium Hydroxide, ES. Energy Environment, 2018.
[22]F.Qiao, Qichao Liang, et al., Efficient ice-bath texturing route for multi-crystalline silicon solar cell application, Silicon, 2018.
[23]Q. Liang, F. Qiao*, et al., Controlling the morphology of ZnO structures via low temperature hydrothermal method and their optoelectronic application, Materials Science in Semiconductor Processing, 2018.
[24]F. Qiao, X.Wang, et al., Functionalized self-assembly of colloidal CdX (X=S, Se) nanorods on solid substrates for device applications, Nanoscale, 2017.
[25]F.Qiao, J.Yang, et al., Fabrication of 3D graphene/CdTe quantum dots composite through electrophoretic deposition and its electrical properties. Journal of Materials Science: Materials in Electronics, 2017.
[26]F. Qiao, W. Xu, et al., Effect of Cd-phosphonate complex on the self-assembly structure of colloidal nanorods, Materials Letters, 2016.
[27]F.Qiao. Semiconductor Nanocrystals for Photovoltaic Devices, Materials Science Forum, 2016.
[28]F.Qiao, Q.Wang, et al., Self-Assembly of Colloidal Nanorods Arrays, International Journal of Nanoscience, 2015.
[29]F.Qiao, J. Bian, et al., Self-assembly of Parallel Aligned Nanorods Monolayer via Thermal Annealing Technique, Materials Letters, 2014.
[30]F.Qiao, Y. Sang. Enhanced photo-induced charge transfer properties of vertically aligned nanorods arrays fabricated by thermal annealing approach, Journal of Materials Science:Materials in Electronics, 2014.
[31]F.Qiao, Y.Sang. Surface photovoltage properties of self-assembled CdSe quantum dots arrays fabricated by slow evaporation approach, Vacuum, 2014.             
[32]F.Qiao. A Novel Method for Preparing Vertically Aligned CdS Nanorod Arrays and Its Application in Photovoltaic Cells with P3HT Fibers, Journal of Inorganic and Organometallic Polymers and Materials, 2013.
[33]F.Qiao, Y.Sang, et al., Enhanced transport properties of assembled CdSe quantum dot through slow evaporation with mixed solvents, Journal of Materials Science:Materials in Electronics, 2013.
[34]F.Qiao. Improved performance of photovoltaic devices based on poly (3-hexylthiophene) nanofibers and CdSe quantum dots through ligand exchange and annealing treatment, Solid-State Electronics, 2013.
[35]F. Qiao, X. Hou, et al., Photovoltaic characterization of poly(2,5-bis(3-dodecylthiophen-2-yl) -2’,2’’-biselenophene) for organic solar cells, Solar Energy Materials & Solar Cells, 2010.
[36]F.Qiao, A.Liu, et al., Bulk heterojunction organic solarcell based on a novel fluorescent fluorine-boron complex, Journal of Material Science, 2009.
[37]F.Qiao, A.Liu, et al., Improved photovoltaic properties of solar cells based on poly[9,9’-dioctyl-fluorene-co-bithiophene] and a soluble fullerene by microwave annealing, Journal of Material Science, 2009.
[38]F.Qiao, A. Liu, et al., Enhanced photovoltaic characteristics of solar cells based on n-type triphenodioxazine derivative, Microelectronics Journal, 2008.
[39]F.Qiao, A.Liu. Optical Properties of Polymer Composites and its Applications in photovoltaic Devices: A Review, Nova Science Publishers, ISBN:978- 1-60876-022-0.
[40]K.Sun, F.Qiao*,J.Yang, et al. Fluff spherical Co–Ni3S2/NF for enhanced hydrogen evolution. International Journal of Hydrogen Energy, 2022.
[41]D.Jin, F.Qiao*, W.Liu, et al. One-step fabrication of MoS2/Ni3S2 with P-doping for efficient water splitting. CrystEngComm, 2022.
[42]Y.Zhao, J.Zheng, J.Yang, W.Liu, F.Qiao*, et al. Hierarchical polypyrrole@ cobalt sulfide-based flexible on-chip microsupercapacitors with ultrahigh energy density for self-charging system. Nano Research, 2023.
[43]L.Zhou, D. L. Danilov, F.Qiao, et al. Sulfur reduction reaction in lithium-sulfur batteries: mechanisms, catalysts, and characterization. Advanced Energy Materials,2022.
[44]L.Zhou, D. L.Danilov, F.Qiao, et al. ZnFe2O4 hollow rods enabling accelerated polysulfide conversion for advanced lithium-sulfur batteries. Electrochimica Acta,2022.
[45]S.Qian, F.Qiao*, L.Zhou, et al. Performance and mechanism analysis of photocatalytic degradation of tetracycline by SiC/CdS composites.CrystEngComm,2022.
[46]Y.Cheng, Y.Liu, Y.Liu, Y.Li, R.Wu, Y.Du, N.Askari, N.Liu, F.Qiao, C.Sun, Z. Kang, H.Li. A core-satellite structured type II heterojunction photocatalyst with enhanced CO2 reduction under visible light, Nano Research, 2022.
[47]W.Liu, M.Yuan, J.Lian, G.Li, Q.Li, F.Qiao, Y.Zhao. Embedding partial sulfurization of iron–cobalt oxide nanoparticles into carbon nanofibers as an efficient electrode for the advanced asymmetric supercapacitor,Tungsten, 2022.
[48]K.Hu, Y.Hu, T.Li, F.Qiao, Y.Chen, J.Han, L.Li, G.Ali, Y.Xie. Hexamethyldisilazane-assisted Mn2+ doping of perovskite nanocrystals under ambient conditions,CrystEngComm, 2022.
[49]Z.Yan, S.Li, Z.Liu, W.Liu, F.Qiao, P.Li, X.Tang, X.Li, J.Yue, Y.Guo, W.Tang, Ti3C2/ϵ-Ga2O3 Schottky Self-Powered Solar-Blind Photodetector with Robust Responsivity,IEEE Journal of Selected Topics in Quantum Electronics, 2022.
[50]W.Xiong, L.Li, F.Qiao, J.Chen, Z.Chen, X.Zhou, K.Hu, X.Zhao,Y.Xie, Air Superhydrophilic-Superoleophobic  SiO2-Based Coatings for Recoverable Oil/Water Separation Mesh with High Flux and Mechanical  Stability, Journal of Colloid and Interface Science, 2021.
[51]K.Hu, Y.Hu, T.Li, F.Qiao, Y.Chen, J.Han, L.Li, G.Ali, Y.Xie, Hexamethyldisilazane-assisted Mn2+ doping of perovskite nanocrystals under ambient conditions,CrystEngComm, 2022.
[52]T.Li, Y.Ding, S. Kareem,F.Qiao, et al., Hexamethyldisilazane-Triggered Room Temperature Synthesis of Hydrophobic Perovskite Nanocrystals with Enhanced Stability for Light-Emitting Diodes,Journal of Colloid and Interface Science,2019.     
[53]W.Qi, J.Graaf, F.Qiao, et al., Ordered Two-Dimensional Superstructures of Colloidal Octapod-Shaped Nanocrystals on FlatSubstrates, Nano Letters, 2012.            
[54]W.Qi, J.Graaf, F.Qiao, et al., Phase diagram of octapod-shaped nanocrystals in a quasi-two-dimensional planar geometry, The Journal of Chemical Physics, 2013.        
[55]S.Liang, G.He*, D.Wang, F.Qiao*. Atomic-layer-deposited (ALD) Al2O3 passivationdependent interface chemistry, band alignment and electrical properties of HfYO/Si gate stacks, Journal of Materials Science & Technology, 2019.

Award winning
1.Third Prize of the 4th Innovation and Entrepreneurship Competition in Jiangsu Province, 2021.
2.Excellence Award of the 4th Innovation and Entrepreneurship Competition in Jiangsu Province, 2021.
3.The first prize of the 5th Jiangsu Innovation and Entrepreneurship Competition, 2022.

Patents
[1]Qiao Fen. A preparation method of nanorod monolayer self-assembly. 2017.01.11, China, ZL201410020328.X.
[2]Qiao Fen. Test support for organic solar cells. 2015.12.09, China, ZL201248103.8.
[3]Qiao Fen. A fixing device for testing the quantum efficiency of organic solar cells. 2017.02.15, China, ZL201310297773.6.
[4]Qiao Fen, Chen Cheng, Mao Baodong. An acid-base secondary texturing method for polysilicon solar cells and polysilicon there of. 2017.11.24, China, ZL201710499684.8.
[5]Qiao Fen. Test stand for organic solar cells. 2013.05.08, China, ZL201277925.1.
[6]Qiao Fen. A fixing device for testing the quantum efficiency of organic solar cells. 2013.12.11, China, ZL201320418972.3.