教育及工作经历

2012年9月至2016年6月，武汉理工大学，材料科学与工程学院，学士

2016年9月至2022年6月，武汉理工大学，材料科学与工程学院，博士

2022年8月至2025年12月，华中科技大学，材料科学与工程学院，博士后

2025年至今，武汉理工大学，交通与物流工程学院，讲师

    研究方向

陶瓷3D打印，结构/功能一体陶瓷，陶瓷摩擦学，半导体用先进陶瓷，

    科研成果：

    主持国家自然科学基金青年基金、中国博士后科学面上基金，参与国家科技重大专项、湖北省重大攻关项目，JKW173项目等多个国家/省部级重点项目；作为主要完成人荣获中国有色金属学会技术发明一等奖（排5）。在Additive Manufacturing、Journal of the European Ceramic Society、Journal of the American Ceramic Society、Composite Part B: Engineering、Material & Design、Cell Reports Physical Science等期刊发表学术论文30余篇（第一或通讯作者16篇），Google引用量700+，H因子15（ESI高被引1篇）。申请发明专利15项，授权5项。Wiley出版社Advanced Material Joining期刊青年编委，Addtive manufacturing、Chemical Engineering Journal、Journal of the European Ceramic Society等期刊审稿人。

    科研项目

    国家自然科学基金青年项目（52405361，30万），主持

    中国博士后科学基金面上项目（2023M741249，8万），主持

    JKW173项目（XXXXXXX，1400万），项目骨干

    国家自然科学基金面上项目（52475355，60万），项目骨干

    国家自然科学基金联合基金（U2341270，259万），项目骨干

    国家科技重大专项（2017-VII-0008-0102，3730万），主要研发人员

    代表性学术成果

   （1）S.X. Zhou, G.Z. Liu,A.N. Chen, J. Su, Y. Zhang, C.S. Wang, C.Z. Yan, Y. S. Shi, Effect of molecular weight and chemical structure of plasticizer on suspension property, binder removal, and sintered performance for zirconia toughened alumina ceramics fabricated by vat photopolymerization.Journal of the European Ceramic Society. 2024, 44, 15: 116730.

    （2）S.X. Zhou,Z.F. Peng, Y. Zhang, C.S. Wang, C.Z. Yan, Y.S. Shi, A novel multifunctional dimethyl adipate plasticizer for vat photopolymerization of high-performance composite ceramics: From inorganic/organic network design to structural engineering applications. Additive Manufacturing. 2026, 119: 105131.

    （3）S.X. Zhou, J. Su, Y. Zhang, K. Liu, C.Z. Yan, Enhancing printing accuracy and defect restraint balance via controlling plasticizer content for ceramic stereolithography: Synergetic light scattering and thermal decomposition kinetics regulation. Journal of Manufacturing Processes. 2025, 156: 834-852.

    （4）S.X. Zhou, F. Zhang, J. Wu,J. Su, K. Liu, Y. Zhang, C.Z. Yan, Y.S. Shi, Anisotropy in ceramic vat photopolymerization: Formation mechanisms, influence on properties, and manipulating strategies. Journal of the European Ceramic Society. 2025, 45, 7: 117249.

    （5）S.X. Zhou, Z.F. Peng, C.Z. Yan, Y.S. Shi, Molecular engineering of dispersants for tailoring rheology in slurry-based ceramic 3D printing: From colloidal control to sintered performance. Journal of the European Ceramic Society. 2026, 46, 8: 118148.

    （6）S.X. Zhou, G.Z. Liu,A.N. Chen, J. Su, Y. Zhang, C.S. Wang, C.Z. Yan, Y. S. Shi, Defect inhibition mechanism of 3D-printed ceramics via synergetic resin composition and debinding processing regulation. Journal of the American Ceramic Society. 2025,108,25: e20168.

    （7）S.X. Zhou, G.Z. Liu, C.S. Wang, C.Z. Yan, Y. S. Shi, Thermal debinding for stereolithography additive manufacturing of advanced ceramic parts: A comprehensive review. Material & Design. 2024, 238: 112632.

    （8）S.X. Zhou, S.C. Zhang, C. Zhang, Fabrication of ZTA crowns with simultaneously improved isotropy on mechanical property and surface quality by DLP.International Journal of the Applied Ceramic technology. 2024, 21: 1593-1615.

    （9）F. Zhang, S.X. Zhou*,H.Y. You, J.Q. Yang, Y.S. Shi, 3D printing of ceramic matrix composites: strengthening and toughening strategies.Composite Part B: Engineering. 2025, 297.

    （10）X.H. Xu,S.X. Zhou*,J.F. Wu, C. Zhang, X. Liu, Inter-particle interactions of alumina powders in UV-curable suspensions for DLP stereolithography and its effect on rheology, solid loading, and self-leveling behavior. Journal of the European Ceramic Society. 2021, 41, 4: 2763-2774.

    （11）X.H. Xu, S.X. Zhou*,J.F. Wu, Q.K. Zhang, Y.X. Zhang, G.Y. Zhu, Preparation of highly dispersive solid microspherical α-Al2O3powder with a hydrophobic surface for stereolithography-based 3D printing technology. Ceramic International. 2020, 46: 1895-1906.

    （12）X.H. Xu, S.X. Zhou*,J.F. Wu, Y. Liu, Y.Y. Wang, Z.C. Chen, Relationship between the adhesion properties of UV-curable alumina suspensions and the functionalities and structures of UV-curable acrylate monomers for DLP-based ceramic stereolithography. Ceramic International. 2021, 47: 32699-32709.

     （13）X.H. Xu, S.X. Zhou*,J.F. Wu, S.H. Liu, S.T. Ma, T.T. Chen, Study of alumina ceramic parts fabricated via DLP stereolithography using powders with different sizes and morphologies. International Journal of the Applied Ceramic technology. 2023, 20: 1167-1193.

    （14）G.Z. Liu, R.Y. Luo, Q. Li, S. Chen, Y. Zhang, C.S. Wang, Q.C. Yang, S.X. Zhou*,C.Z. Yan,Y.S. Shi,Bifunctional nano-SiO2additive for reinforcing the SiC/Al composites fabricated via a novel hybrid additive manufacturing. Composite Part B: Engineering. 2024, 283: 111647.

    （15）周士翔，孙冬，陈双，闫春泽，史玉升,空心涡轮叶片铸造用铝基陶瓷铸型的激光选区烧结成形，精密成形工程，2024, 16: 82-90.

    （16）周士翔，闫春泽，史玉升，激光选区烧结在铸造领域的应用现状与发展趋势，铸造，2026,75: 232-238.

     发明专利：

    （1）一种黑刚玉基TPMS吸热陶瓷的光固化3D打印制备方法(CN117700212B，授权)

    （2）一种光固化3D打印用球形Al2O3粉体的制备方法（CN202010891684.4，授权）

    （3）一种利用固相法合成的绿松石陶瓷色料及其制备方法（CN202011439484.1，授权）9

    （4）一种UV光固化3D打印用高固含量低粘度Al2O3陶瓷料浆的制备方法（CN202011325999.9，授权）

    （5）一种喷墨打印用水性黄色陶瓷墨水及其制备方法（CN111253803B，授权）

    （6）一种氮化钛碳化硅吸热储热异质陶瓷骨架的多材料光固化3D打印一体化的制备方法（CN202311856540.5）

    （7）一种光固化3D打印结合CVD制备太阳能热发电用TiN/AlN吸储热一体TPMS异质陶瓷骨架的方法（CN202311856062.8）

    （8）一种光固化3D打印多材料陶瓷结构件的制备方法（CN202410350710.0）

    （9）一种基于光固化3D打印的着色氧化物陶瓷的两步成形法（CN202311611525.4）

   （10）一种用于DLP光固化3D打印的高附着性能陶瓷浆料的制备方法（CN202111633519.X）

    （11）一种水基光热双效固化陶瓷浆料及其制备方法与应用（CN202310878979.1）

    （12）分散剂组合物包括分散剂组合物的陶瓷浆料及其制备方法和在制备陶瓷基板中的应用 （CN202411674939.6）

    （13）流延浆料及其制备方法（CN202411362176.1）

    （14）陶瓷生坯及其制备方法（CN202411169189.7）

    （15）原位化学沉积包覆氮化铝陶瓷的方法及氮化铝陶瓷（CN2024111089224）