澳门·威尼克斯人(中国区)官方网站

Zhangwei CHEN      Professor

Sex:

Email: chen@szu.edu.cn

Office: 1010 Huixing Building

Talent title: Shenzhen Peacock Talent

Final degree: PhD

Tel: 86-755-26531066

Advisor qualification: Master Supervisor/foreign PhD Co-Supervisor

Research Interest:

●Additive Manufacturing and 3D Printing;
●Additive manufacturing of high performance ceramics;
●Development of ceramic-based materials for 3D printing;
●Structural and functional ceramic devices and characterizations;
●Integral structure-property design and 3D printing;
●3D printing of polymer-based materials;
●3D printing of metals;
●Methods used include: photopolymerization, inkjet printing, direct ink writing and selective laser melting.
[Foreign PhD and Postdoc positions available with highly competitive pay, please contact via chen@szu.edu.cn for more details.]

Undergraduate Course:

Graduate Course:

Education:

2010-2014 Imperial College London, UK, PhD
2007-2010 Xi’an Jiaotong University, China, ME
2005-2007 Ecole Centrale de Lyon, France, Diplome d’Ingenieur (=Master)
2003-2007 Xi’an Jiaotong University, China, BE

Career:

2018-present Shenzhen University, Professor and Executive Director of Additive Manufacturing Institute
2016-2018 Shenzhen University, Associate Professor and Vice Director of Additive Manufacturing Institute
2014-2016 Imperial College London, UK, Postdoc Research Associate

Publication:

● 2020
[1]    Recent progress on the fabrication of energy devices based on inkjet printing, under review
[2]    Research advances of extrusion and jetting-based additive manufacturing of ceramics, under review
[3]    Additive manufacturing of polymer-derived ceramics: A comprehensive review, under review
[4]    Additive manufacturing of thin ceramic electrolyte using highly stable inks, under revision
[5]    Dimensional retention of photocured ceramic units during 3D printing and sintering processes, under review
[6]    Conformal organosilicon polymer coating on metal-organic framework enables multifunctional Zn-C@SiOC nanocomposite as a high-performance anode material for lithium-ion batteries, under review
[7]    Fabrication of Smart Clay Soil Using Additive Manufacturing and FBG Technology, under review
[8]    A Review of Current Performance of Rare Earth Metal-Doped Barium Zirconia: the Promising Electrode and Electrolyte Material for the Protonic Ceramic Fuel Cells, under review
[9]    A Review of Iron Selenide Based Material-An Emerging Electrocatalyst: Synthesis, Structural Property and Current Performances, under review
[10]    The Significance of Additive Manufacturing towards Improved Fuel cell Fabrication: A Comprehensive Review, under review
[11]    Enhanced strength-ductility synergy of selective laser melted reduced activation ferritic/martensitic steel via heterogeneous microstructure modification, Materials Science & Engineering A, accepted
[12]    Ordered nitrogen complexes overcoming strength-ductility trade-off in an additively manufactured high entropy alloy, Virtual and Physical Prototyping, accepted
[13]    HC Wang, Y Hong, Z Chen, et al., ZnO UV Photodetectors Modified by Ag Nanoparticles Using All-Inkjet-Printing, Nanoscale Research Letters 15 (1): 1-8 (2020) (IF:3.58)
[14]    SA Rasaki, Z Chen, H Shen, et al., Cobalt Nanoparticles Modified Single-Walled Titanium Carbonitride Nanotube Derived from Solid-Solid Separation for Oxygen Reduction Reaction in Alkaline Solution, Electrocatalysis, 1-14 (2020) (IF:2.57)
[15]    C Liu, D Yan, J Tan, Z Mai, Z Cai, Y Dai, M Jiang, Pei Wang, Z Liu, C Li, C Lao*, Z Chen*: Development and Experimental Validation of a Hybrid Selective Laser Melting and CNC Milling System, Additive Manufacturing, 36:101550 (2020). (IF:7.17)
[16]    Y Liu, Z Chen* et al.: 3D printing of ceramic cellular structures for potential nuclear fusion applications, Additive Manufacturing, 35 (2020). (IF:7.17)
[Reported by Science Daily Newspaper: http://digitalpaper.stdaily.com/http_www.kjrb.com/kjrb/html/2020-07/20/content_448902.htm?div=-1]
[17]    C Liu, …, Z Chen* et al.: Effect of Hot Isostatic Pressing on Microstructures and Mechanical Properties of Ti6Al4V Fabricated by Electron Beam Melting, Metals, 10(5): 593 (2020) (IF: 2.26)
[18]    S Rasaki, Z Chen* et al.: Anti-Perovskite Metal Carbides: a New Family of Promising Electrocatalysts for Oxygen Reduction in Alkaline Solution, Materials Research Bulletin, 133: 111014 (2020) (IF: 4.02)
[19]    P Qu... Z Chen*: Inkjet printing of porous ceramic electrodes used in SOFCs, Journal of the Chinese Ceramic Society, 48(10): 1-10 (2020). (in Chinese, EI)
[20]    Y Liu, Z Chen*: Research progress on stereolithography-based 3D printing of ceramics, Journal of Materials Engineering, 48(9): 1-12 (2020). (in Chinese, EI)
[21]    Z Li, Z Chen* et al.: Additive manufacturing of lightweight and high-strength polymer-derived SiOC ceramics. Virtual and Physical Prototyping, 1-15 (2020). (IF:6.83)
[22]    Z Chen*, Z Gong, et al.: Characterization of indentation microstructures of porous SOFC cathodes. Ceram. Int., 46(1): 803-812 (2020) (IF:3.45)
[23]    P Wang, A Gebert*, L Yan, H Li, C Lao, Z Chen, K Kosiba, U Kühn, S Scudino, Corrosion of Al-3.5Cu-1.5 Mg–1Si alloy prepared by selective laser melting and heat treatment, Intermetallics, 124: 106871 (2020) (IF:3.4)
[24]    P Wang*, C Lao, Z Chen, Y Liu, H Wang, H Wenrock, J Eckert, S Scudino, Microstructure and mechanical properties of Al-12Si and Al-3.5Cu-1.5Mg-1Si bimetal fabricated by selective laser melting, J. Mat. Sci. Tech. 36: 18-26 (2020) (IF: 5.04)

●    2019
[25]    Z Chen*, Z Li, et al.: 3D printing of ceramics: A review. J.Eur.Ceram.Soc., 39(4): 661-687(2019) (IF:4.029)    
[ESI 1% Highly Cited Paper, 0.1% Hot Paper]
[26]    Z Chen*, C Liu, et al.: Mechanical properties and microstructures of 3D printed bulk cordierite parts, Ceram. Int., 45(15): 19257-19267 (2019) (IF:3.45)
[27]    Z Chen*, J Li, et al.: Preparation of high solid loading and low viscosity ceramic slurries for photopolymerization 3D printing. Ceram.Int., 45(9): 11549-11557 (2019) (IF:3.45)
[28]    M Jiang, Z Chen* et al.: Strong and ductile reduced activation ferritic/martensitic steel additively manufactured by selective laser melting. Mater. Res. Lett., 7(10): 426-432 (2019) (IF:6.161)
[29]    Y Fu, Z Chen* et al.: Preparation and stereolithography 3D printing of ultralight and ultrastrong ZrOC porous ceramics. J.All.Compd., 789: 867-873 (2019) (IF: 4.175)
[30]    C Liu, J Tong, J Ma, D Wang, F Xu, Y Liu, Z Chen*, C Lao*, Low Temperature Deposition Manufacturing: A Versatile Materials Extrusion-based 3D Printing Technology for Fabricating Hierarchically Porous Materials, Journal of Nanomaterials, 1291067 (2019) (IF: 2.233)
[31]    C Liu*, F Xu, Y Liu, J Ma*, P Liu, C Lao, Z Chen*. High Mass Loading Ultrathick Porous Li4Ti5O12 Electrodes with Improved Areal Capacity Fabricated via Low Temperature Direct Writing, Electroch. Acta, 314: 81-88 (2019) (IF: 5.383)
[32]    C Liu*, F Xu, X Cheng, J Tong, Y Liu, Z Chen, C Lao, J Ma*. Comparative study on the electrochemical performance of LiFePO4 cathodes fabricated via low temperature 3D printing, direct ink writing and conventional roller coating process. Ceram.Int., 45(11): 14188-14197 (2019) (IF:3.45)
[33]    C Liu, J Tong, M Jiang, Z Chen, X Wu, M Xu, H Liao, P Wang, G Xu, C Lao, Effect of scanning strategy on microstructure and mechanical properties of selective laser melted reduced activation ferritic/martensitic steel, Mat. Sci. Eng. A, 766: 138364 (2019) (IF:4.081)
[34]    X Jiang, W Li, T Hai, R Yue, Z Chen, C Lao, Y Ge, G Xie, Q Wen, H Zhang, Inkjet-printed MXene micro-scale devices for integrated broadband ultrafast photonics, npj 2D Materials and Applications, 3(1): 1-9 (2019) (IF:9.06)

●    2018
[35]    Z Chen* et al.: Development and characterizations of novel aqueous-based LSCF suspensions for inkjet printing. Ceram.Int., 44(11): 13381-13388(2018) (IF:3.45, )
[36]    Z Chen* et al.: Numerical Study of Solid Oxide Fuel Cell Contacting Mechanics. Fuel Cells, 18 (1): 42-50(2018) (IF:2.33)【Front Cover Paper】
[37]    P Gao, S Xu, Z Chen, X Huang, Z Bao, C Lao, G Wu, Y Mei: Flexible and Hierarchically Structured Sulfur Composite Cathode Based on the Carbonized Textile for High-Performance Li–S Batteries. ACS applied materials & interfaces 10(4): 3938-3947(2018)(IF:8.456)
[38]    Y Fu, G Xu, Z Chen, D Wang, C Lao: Multiple metals doped polymer-derived SiOC ceramics for 3D printing. Ceram.Int., 44(10):11030-11038(2018)(IF:3.45, )
[39]    C Liu, N Huang, F Xu, J Tong, Z Chen, X Gui, Y Fu, C Lao: 3D Printing Technologies for Flexible Tactile Sensors toward Wearable Electronics and Electronic Skin. Polymers, 10(6):629 (2018)(IF:3.164)

●    2017
[40]    Z Chen* et al.: Spherical indentation of bilayer ceramic structures: Dense layer on porous substrate. J.Eur.Ceram.Soc., 37(15):4763-4772(2017) (IF:4.029, )
[41]    Z Chen* et al.: Analysis of spherical indentation of porous ceramic films. J.Eur.Ceram.Soc., 37(3):1031-1038(2017) (IF:4.029, )【Feature Article】
[42]    M Biton, V Yufit, F Tariq, Z Chen, N Brandon: Integrating multi-length scale high resolution 3D imaging and modelling in the characterisation and identification of mechanical failure sites in electrochemical dendrites. Acta Materialia, 141:39-46(2017)(IF:7.293, )
[43]    C Liu, X Cheng, B Li, Z Chen, S Mi, C Lao: Fabrication and characterization of 3D-printed highly-porous 3D LiFePO4 electrodes by low temperature direct writing process. Materials, 10(8):934-946(2017) (IF:2.972)

●    2016
[44]    Z Chen* et al.: Inkjet printing and nanoindentation of porous alumina multilayers. Ceram.Int., 42(7):8316-8324(2016) (IF:3.45, )
[45]    Z Chen* et al.: Spherical Indentation of Porous Ceramics: Cracking and Toughness. J.Eur.Ceram.Soc., 36(14): 3473-3480(2016) (IF:4.029, )
[46]    Z Chen* et al.: Spherical indentation of porous ceramics: elasticity and hardness. J.Eur.Ceram.Soc., 36(6):1435-1445(2016) (IF:4.029, )

●    2015
[47]    Z Chen* et al.: Microstructural characteristics and elastic modulus of porous solids. Acta Materialia, 89: 268-277(2015) (IF:7.293, )
[48]    Z Chen* et al.: Fracture Toughness of Porous Material of LSCF in Bulk and Film Forms. J.Am.Ceram.Soc. 98(7):2183-2190(2015) (IF:3.094, )
[49]    Z Chen* et al.: Analyses of microstructural and elastic properties of porous SOFC cathodes based on FIB tomography. J.PowerSources, 273:486-494(2015) (IF:7.467, )
[50]    F Tariq, M Kishimoto, G Cui, V Yufit, M Lomberg, E Ruiz-Trejo, Z Chen, N Brandon: Advanced 3D Imaging and Analysis of SOFC Electrodes, ECS Transactions, 64(2): 81-86(2015)

●    2014
[51]    Z Chen* et al.: Surface quality improvement of porous thin films for nanoindentation. Ceram.Int., 40(3):3913-3923(2014) (IF:3.45, )
[52]    F Tariq, V Yufit, Y Merla, M Biton, B Wu, Z Chen et al.: In-Operando X-ray Tomography Study of Lithiation Induced Delamination of Si Based Anodes for Lithium-Ion Batteries, ECS Electrochem.Lett. 3(7):A76-A78(2014) (IF:1.771)
[53]    X Wang, F He, Z Chen et al.: Porous LSCF-3YSZ interface fracture toughness measured by single beam wedge test. J.Eur.Ceram.Soc. 34(10):2351-2361(2014) (IF:4.029, )

●    2013
[54]    Z Chen* et al.: Nanoindentation of porous bulk and thin films of La0.6Sr0.4Co0.2Fe0.8O3-δ. Acta Materialia, 61(15): 5720-5734(2013)(IF:7.293, )
[55]    X Wang, Z Chen et al.: Crack formation in ceramic films used in solid oxide fuel cells. J.Eur.Ceram.Soc., 33(13-14):2539-2547(2013)(IF:4.029, )

●    2012 and earlier
[56]    Z Chen* et al.: Process parameters appraisal of ceramic fabrication via stereolithography using Taguchi method. J.Eng.Manuf., 226(7):1249-1258(2012)(IF: 1.752)
[57]    X Tian, D Li, Z Chen: Study on the fabrication accuracy of ceramic parts by direct stereolithography, Virtual and Physical Prototyping 7(3):195-202(2012) (IF:6.852)
[58]    W Zhou, D Li, Z Chen: Influence of ingredients of silica suspensions on UV curing behavior of ceramic suspensions. Int.J.Adv.Manuf.Tech. 52(5-8):575-582(2011)(IF:2.601)
[59]    Z Chen* et al.: Curing characteristics of ceramic stereolithography for an aqueous-based silica suspension. J.Eng.Manuf., 224(4): 641-651(2010) (IF:1.752)
[60]    W Zhou, D Li, Z Chen, Direct fabrication of an integral ceramic mould by stereolithography, J.Eng.Manuf. 224(2):237-243(2010)(IF:1.752)
[61]    W Zhou, D Li, Z Chen, B Lu: Curing Behaviors of Ceramic Suspension in Stereolithography and Its Engineering Applications, Aeronautical Manufacturing Technology, 8:36-42(2010) (in Chinese)
[62]    W Zhou, D Li, Z Chen, B Lu: Direct fabrication process of ceramics based on stereolithography, Journal of Plastic Engineering, 16(3):198-201(2009) (in Chinese)

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