Farhad Saba, 工学博士，中国-伊朗合作培养（2015-2018）（2019.9-上海交大金属基复合材料国家重点实验室博士后）；

李萍，工学硕士，2014.07-2017.04 国家奖学金获得者，工作去向：台积电（昆山）；

王利利，工学硕士，2014.07-2017.06 苏州工业园奖学金，工作去向：泰州民企；

刘苏丽，工学硕士，2015.07-2018.05 国家奖学金获得者，工作去向：德国罗伯特.博世集团（南京）；

赵佩佩，工程硕士，2015.07-2018.06 光华奖学金，工作去向：美国森萨塔SENSATA ，中芯国际；

刘腾飞，工学硕士，2016.07-2019.06 工作去向：昆山汽车零部件企业（昆山）；

王   娟，工学硕士，2017.07-2020.06 工作去向：江苏时代新能源公司；

杜茂龙，工学硕士，2017.07-2020.03 工作去向：安徽民企；

范阔威，工程硕士，2017.07-2020.03 工作去向：迈瑞医疗南京分公司。

张彬，   工学硕士， 2018.07-2021.06  工作去向：中车常州研究院。

叶灿，   工程硕士，2018.07-2021.09   工作去向：中兴通讯。

张瀚琳,  工学硕士，2019.07-2022.07  工作去向：中兴通讯。

邓传迅，工学硕士，2019.07-2022.07 工作去向：杭州半导体公司。

商彩云，工学博士，2019.03-2023.07 工作去向：南京工程学院 讲师

黄宜诺, 工学硕士，2021.08-2024.07 工作去向：华为上海分公司

万齐法，工学博士，2021.03-2024.12 工作去向：南昌航空大学 讲师

熊义峰，工学博士，2020.09-2025.03 工作去向：广东（东莞）材料基因高等理工研究院。

冯慧雅，工学硕士，2022.08.2025.07深圳半导体公司，

汤屹洲，工学硕士，2022.08.2025.07 深圳范林半导体。

李慧，  工程博士，2005.12毕业，工作去向：南通瑞祥新材研发部

目前在读博士生4人（张瀚琳，莱芭，优斯曼，杨勇），硕士研究生4人（胡宇航，栾恩志，李柯汛，滕昱斌）。欢迎对复合材料，高熵合金与陶瓷，激光3D打印材料成型新技术等感兴趣的同学报考硕士与博士生。

[1] 装备预研教育部联合基金项目：XX仿生装甲新材料XXX. 2021.12-2023.12, 主持，在研，经费75万元；本项目主要研究一种新型的仿生装甲材料，应用于一些武器上，实现轻量化和多功能性。为我国武器装备更新换代做出应有的贡献。

[2]  企业横向项目：高熵陶瓷系列粉末、块体与多孔体的制备技术与应用，2021-2024，主持，在研; 本项目主要研究FeCoNiCr系列高熵合金陶瓷材料粉末、块体与多孔体的制备技术、性能与用途，实现批量化生产进入市场，部分代替目前的氧化铝、氧化锆、氧化硅等陶瓷材料，应用于一些高端涂层，防高温装备、耐烧蚀、电磁波防护、隐身性能的高端场合应用。

[1] 国家自然科学基金面上项目，激光3D打印高熵合金增强钛合金基复合材料的界面调控机理。2023.01-2026.12, 主持，在研。

[2] 装备预研教育部联合基金项目：XX仿生装甲新材料XXX. 2021.12-2023.12, 主持，在研；

[3]  企业横向项目：高熵陶瓷系列粉末、块体与多孔体的制备技术与应用，2021-2026，主持，在研;

[4]  国家自然科学基金NSFC-航天先进制造联合基金，航天用石墨烯增强钛基复合材料. 2018.01-2020.12，主持，结题.

[5]  江苏省自然科学基金面上项目.直流脉冲电场诱导纳米碳的相变机理研究。2016.8-2019.08,主持，结题.

[6]  2017创聚江宁创新创业项目，等离子烧结制备高纯稀有金属及其合金靶材及其产业化，主持，在研

[7]  国家人力资源和社会保障部留学人员科技活动项目择优资助项目.放电等离子烧结合成金刚石新技术的研究。2016-2019.主持，在研

[8]  国家教育部回国留学人员科研启动基金. 等离子烧结合成金刚石的机理.No. 2015-1098.主持.在研

[9]  中国科学院上海硅酸盐研究所高性能陶瓷和超微结构国家重点实验室开放基金，纳米金刚石及其复合材料. SKL201603SIC. 2017.01-2018.12, 主持，在研.

[10]  中南大学粉末冶金国家重点实验室开放课题优先资助项目，三维纳米多孔钛的制备与微结构调控机制，2014-2016，主持，在研。

发表的SCI论文：

2026.

[1] Hui Li,Faming Zhang*, Xiang Liu, Wei Zheng, Guobing Ying. Ultrahigh compressive strength(TiZrNbTa)2AlC MAX phase enabled by high entropy design and its derivativeMXene. Journal of Materials Science and Technology. 2026, 273, 40-48

[2] Laiba Shaukat, Yizhou Tang, Yifeng Xiong, Faming Zhang*.Achieving synergistic strengthening of selective laser melted titanium alloywith CoCrFeNi medium-entropy alloy. Materials Science & Engineering A 955(2026) 149897

[3] Yuhang Hu, Faming Zhang*, Yifeng Xiong,Wubian Tian. Mechanicalproperties and corrosion resistance of titanium alloy matrix compositesreinforced with partially decomposed FeCoNiCrTi0.8 high entropy alloy. Journalof Alloys and Compounds 1050 (2026) 185797

[4]Laiba Shaukat, Yinuo Huang, Yifeng Xiong , Faming Zhang*. Selective lasermelting of high entropy alloy of FeCoNiCrMo reinforced Ti6Al4V alloy withenhanced dynamic mechanical properties. Materials Letters 402 (2026) 139365

2025

[1] Qifa Wan, FamingZhang*, Yifeng Xiong. High-entropy engineering enables spinel oxides towardhigh-performance infrared radiation materials. Chemical Engineering Journal,506 (2025)160248 （Q1）

[2] Yifeng Xiong, Faming Zhang, Yinuo Huang, Ting Dai, Qifa Wan, Yan Chen,Shuo Yin. A novel composites of laser 3D printed CoCrFeNiMn/Ti6Al4V latticestructure with B4C/AlSi10Mg interpenetrating phases. Composites Part A,188(2025)108579  （Q1）

[3]Yifeng Xiong, Yuhang Hu, Faming Zhang, Qifa Wan, Yan Chen, WeihaoYuan,Shuo Yin, Caiyun Shang, Enhancing strength and ductility in Ti64 Alloys:Optimizing dual-phase heterostructures and TRIP effects via high-entropy alloycontent modulation, Materials & Design 257 (2025) 114399

[4]Yizhou Tang, Faming Zhang*, Yifeng Xiong, Yuhang Hu, Huiya Feng,Interface microstructure and strengthening mechanisms of medium-entropy alloyFeCoNiCr particle reinforced titanium composites, Materials Science &Engineering A 935(2025)148359

[5]Huiya Feng, Faming Zhang*, Yifeng Xiong, Yuhang Hu, Yizhou Tang, Effectof FeCoNiCrMn addition on the Ti6Al4V alloy fabricated by spark plasmasintering and selected laser melting，Journal of Alloysand Compounds，1030(2025)180837

[6]Hui Li, Faming Zhang,*, Qifa Wana, Weiwei Sun. Synergistic Sisubstitution and in-situ Al2O3 for enhanced mechanical and oxidation resistantproperties of Ti3AlC2, Ceramics International 51(2025)39486–39497

2024

[1]  Yifeng Xiong, Faming Zhang*,Yinuo Huang, Ting Dai, Qifa Wan, Yan Chen & Shuo Yin. Achieving superiorstrength-ductility combination in the heterogeneous microstructured Ti64 alloyvia multi-eutectoid elements alloying with CoCrFeNiMn during laser powder bedfusion. Virtual and Physical Prototyping,2024, 19:1, e2375106. （Q1）

[2]  Qifa Wan, Faming Zhang*,Yifeng Xiong.New spinel-structured high-entropy oxides with high- andstable-infrared radiation properties. Journal of American Ceramic Society.2024; 1-10. （Q1）

[3]  Qifa Wan, Faming Zhang*, Yifeng Xiong. Facile synthesis,characterization, and mechanical properties of spinel-structured high-entropyoxides: Lattice distortion and sluggish diffusion effects induced by aluminumcation. Journal of the European CeramicSociety 44 (2024) 6629-6640（Q1）

[4]  Yinuo Huang, Faming Zhang*,Yifeng Xiong , Ting Dai, Qifa Wan. Selective laser melting processing ofheterostructured Ti6Al4V/ FeCoNiCrMo alloy with superior strength and ductility.Journal of Alloys and Compounds 978 (2024) 173435

2023

[1] CaiyunShang, Faming Zhang*, Yifeng Xiong, Qifa Wan, FengChen. Spark plasma forgingand network size effect on strength-ductility trade-off in graphene reinforcedTi6Al4V matrix nanocomposites. MaterialsScience and Engineering: A, 2023, 862:144480

[2] QifaWan, Faming Zhang *, Yifeng Xiong, Caiyun Shang. Formation, thermal stability,and infrared radiation properties of spinel-structured high-entropy oxides inCo–Mn–Fe–Cr–Ni–Zn–O system. CeramicsInternational, 2023, 08, 228.

2022

[1]  Hanlin Zhang, Faming Zhang*, Li Fu b, Qifa Wan. Spark plasma sinteringassisted rapid growth of titanium boride layers on titanium: Microstructuresand growth kinetics. Surface & Coatings Technology 432 (2022) 128083

[2]  ChuanxunDeng, Faming Zhang*, · Daming Chen, ·Genxi Yu, Wenjing Zhao, Yifeng Xiong,Caiyun Shang, Jian Chen, Qingyu Xu. Improved electrochemical performance ofcarbon nano‑onions conductive additives for LiFePO4/C cathode material. Ionics (2022) 28:4485-4494

[3]  CaiyunShang, Faming Zhang *, Juan Wang, Feng Chen. Interface configuration effect onmechanical and tribological properties of three-dimension network architecturaltitanium alloy matrix nanocomposites. Composites:Part A 158 (2022) 106981

[4]  Qifa Wan,Bin Zhang, Faming Zhang*, Caiyun Shang, and Yifeng Xiong. Interface-reactionreduction and hot rolling deformation of network structured graphene-TiBwhiskers/Ti6Al4Vcomposites by spark plasma sintering. Journal of Materials Science, 2022, 57: 20601–20614.

[5]  YifengXiong, Faming Zhang*, Yinuo Huang, Caiyun Shang, Qifa Wan. Multiplestrengthening via high-entropy alloy particle addition in titanium matrixcomposites fabricated by spark plasma sintering. Materials Science & Engineering A 859 (2022) 144235

[6]  YifengXiong, Faming Zhang*, Ting Dai, Caiyun Shang, Qifa Wan. Crystal growthmechanism and mechanical properties of Ti-6Al-4V alloy during selective lasermelting. Materials Characterization194 (2022) 112455

2021.

[1]  Yifeng Xiong, Maolong Du, Faming Zhang*, Farhad Saba, Caiyun Shang. Preparationand mechanical properties of titanium alloy matrix composites reinforced byTi3AlC and TiC ceramic particulates. Journal of Alloys and Compounds 886 (2021)161216.

[2]  Bin Zhang, Faming Zhang*, Farhad Saba, Caiyun Shang. Graphene-TiC hybridreinforced titanium matrix composites with 3D network architecture:Fabrication, microstructure and mechanical properties. Journal of Alloys andCompounds 859 (2021) 157777

[3]  Farhad Saba, Behzad Nateq, Seyed Abdolkarim Sajjadi, Faming Zhang, SiminHeydari.The enhanced mechanical properties and strain-hardening capability ofCNT/Al composites achieved by heterogeneous micro-laminated architecture. CompositesCommunications 27 (2021) 100861

[4]  叶灿，张法明. 异构结构纳米金刚石/钛基复合材料的微观组织与力学性能.精密成形工程. 2021.13（3）：62-69

2020

[1]  FamingZhang, Kuowei Fan, Farhad Saba, Jin Yu. Graphene reinforced-graphitizednanodiamonds matrix composites:Fabrication, microstructure, mechanicalproperties, thermal and electrical conductivity. Carbon, 169(2020)416-428.

[2]  CaiyunShang, Faming Zhang, Bin Zhang, Feng Chen. Interface microstructure andstrengthening mechanisms of multilayer graphene reinforced titanium alloymatrix nanocomposites with network architectures. Materials and Design, 2020, https://doi.org/10.1016/j.matdes.2020.109119

[3]  CaiyunShang, Tengfei Liu, Faming Zhang, Feng Chen. Effect of network size onmechanical properties and wear resistance of titanium/nanodiamondsnanocomposites with network architecture.Composites Communications, 19 (2020) 74–81.

[4]  KuoweiFan, Faming Zhang, Caiyun Shang, Farhad Saba, Jin Yu. Mechanical properties andstrengthening mechanisms of titanium matrix nanocomposites reinforced withonion-like carbons. Composites Part A,132 (2020) 105834.

[5]  FarhadSaba, Elham Garmroudi-Nezhad, Faming Zhang, Lili Wang. Fabrication, mechanicalproperty and in vitro bioactivity of hierarchical macro-/micro-/nano-poroustitanium and titanium molybdenum alloys. Journalof Materials Research, 2020,doi:10.1557/jmr.2020.12

[6]  FamingZhang, Juan Wang, Tengfei Liu, Caiyun Shang. Enhanced mechanical properties offew-layer graphene reinforced titanium alloy matrix nanocomposites with anetwork architecture. Materials andDesign, 186 (2020) 108330.

[7]  FamingZhang, Maolong Du, Kuowei Fan, Can Ye, Bin Zhang. Fabrication and mechanicalproperties of network structured titanium alloy matrix composites reinforcedwith Ti2AlC particulates. MaterialsScience & Engineering A, 776 (2020) 139065.

[8]  TaoWen, Kuowei Fan, Faming Zhang. High strength and high ductility in nickelmatrix nanocomposites reinforced by carbon nanotubes and onion-like-carbonhybrid reinforcements. Journal of Alloysand Compounds, 814 (2020) 152303.

[9]  王娟, 张法明* , 商彩云, 张彬.石墨烯/钛基复合材料的界面反应控制、微观组织和压缩性能. 复合材料学报，2020，37（12）：3137-3148.

[10]  刘腾飞，张法明*，王娟. 纳米金刚石含量对网状结构钛基复合材料组织与性能的影响. 稀有金属材料与工程,2020, 49(3):1068-1074

2019

[1]  FamingZhang, Kuowei Fan, Jin Yu, Farhad Saba and Jing Sun. Pulsed direct currentfield-induced thermal stability and phase transformation of nanodiamonds tocarbon onions. RSC Adv., 2019, 9,14360

[2]  FarhadSaba, Faming Zhang, Suli Liu, Tengfei Liu. Reinforcement size dependence ofmechanical properties and strengthening mechanisms in diamond reinforcedtitanium metal matrix composites, Composites B. 2019, 167:7-19.

[3]  FamingZhang, Tengfei Liu. Nanodiamonds reinforcedtitanium matrix nanocomposites with network architecture. Composites B. 2019, 165:143-154.

2018

[1]  FarhadSaba, Seyed Abdolkarim Sajjadi, Mohsen Haddad-Sabzevar, Faming Zhang. Exploring the reinforcing effectof TiC and CNT in dual-reinforced Al-matrix Composites. Diamond & Related Materials 89 (2018) 180–189.

[2]  Farhad Saba, Faming Zhang, Suli Liu, Tengfei Liu. Tribological properties, thermal conductivity and corrosion resistance oftitanium/nanodiamond nanocomposites. Composites Communications. 2018, 10:57-63.

[3]  FamingZhang, Peipei Zhao, Teifei Liu, Suli Liu, Zhang Peigen, Jin Yu, Jing Sun.In-situ synthesis of nanodiamonds reinforced iron-nickel matrix nanocompositesand their properties. Diamond andrelated Materials. 2018, 83:60-66.

[4]  Saba,Farhad; Sajjadi, Seyed Abdolkarim; Zhang, Faming. The effect of TiC: CNT mixingratio and CNT content on the mechanical and tribological behaviors of TiCmodified CNT-reinforced Al-matrix nanocomposites. Powder Technology, 2018,331: 107-120.

[5]  FarhadSaba, Seyed Abdolkarim Sajjadi, Mohsen Haddad-Sabzevar, Faming Zhang.TiC-modified carbon nanotubes, TiC nanotubes and TiC nanorods: Synthesis andcharacterization. Ceramics International.2018, 44:7949-7954.

2017

[1]  Faming Zhang, Suli Liu, Peipei Zhao, Tengfei Liu, Jing Sun.Titanium/nanodiamond nanocomposites: Effect of nanodiamond on microstructureand mechanical properties of titanium. Materialsand Design, 2017, 131:144-155

[2]  Faming Zhang, Ping Li, Jin Yu et al. Fabrication, formation mechanismand properties of three-dimensional nanoporous titanium dealloyed in metallicpowders. Journal of MaterialsResearch 2017, 32(8)1528-40.

[3]  Faming Zhang, Lili Wang, Ping Li, Suli Liu, Peipei Zhao, GeDai and Siyuan He. Preparation of Nano to Submicro-Porous TiMo Foams bySpark Plasma Sintering. AdvancedEngineering Materials, 2017, 19(2):1-10. 

[4]  Farhad Saba， SeyedA. Sajjadi，MohsenHaddad-Sabzevar, Faming Zhang. Formation mechanism of nano titanium carbide onmulti-walled carbon nanotube and influence of the nanocarbides on theload-bearing contribution of the nanotubes inner-walls in aluminum-matrixcomposites. Carbon, 2017, 115C:720-729.

2016

[1]  Farhad Saba， FamingZhang，Seyed A. Sajjadi，Mohsen Haddad-Sabzevar，Ping Li，Pulsed current fieldassisted surface modification of carbon nanotubes with nanocrystalline titaniumcarbide，Carbon，2016，101：261-271.

[2]  Faming Zhang，PingLi，Ge Dai，Siyuan He，Fabrication and propertiesof three-dimensional nanoporous graphene foams with magnesium binder，Scripta Materialia，2016，111：89-93.

2008-2014 在德国期间的工作

[1]F. Zhang, F. Essenhut, E. Burkel. Pulsed direct current field induced phase transformation in graphene nanoplatelets. Applied Physics Letters. 104, 253108 (2014).

[2]Yujie Quan, Philipp Drescher, Faming Zhang, Eberhard Burkel, Hermann Seitz, Cellular Ti6Al4V with carbon nanotubelike structures fabricated by selective electron beam melting. Rapid Prototyping Journal, 2014,20(6):541 – 55

[3]F. Zhang, M. Reich, O. Kessler, E. Burkel.  Potential of rapid cooling spark plasma sintering for metallic materials. Materials Today. 2013, 16(5): 192-195.

[4]F. Zhang, B. Basu, L. Wang, F. Izabel, E. Claude. Editorial: Nanomaterials Processed by Spark Plasma Sintering. Journal of Nanomaterials, 2013, doi:10.1155/2013/346952.

[5]Y Quan, F. Zhang, H. Rebl, B. Nebe, O. Kessler, E. Burkel. Ti6Al4V foams fabricated by spark plasma sintering with post heat treatment. Materials Science & Engineering A. 2013, 565(118–125).

[6]F. Zhang, F. Ahmed, G. Holzhuter, E. Burkel. Growth of diamond from fullerene C60 by spark plasma sintering. Journal of Crystal Growth. 340 (2012) 1–5.

[7]F. Zhang, F. Ahmed, J. Bednarcik, E. Burkel. Diamond synthesis through the generation of plasma during spark plasma sintering. Phys. Status Solidi A, 2012, 11: 2241–2246.

[8]F. Zhang, A. Weidmann, J. B. Nebe, E. Burkel. Cell Response to Surface Modified Carbon Nanotubes. Materials Science and Engineering: C, 2012, 32(5): 1057–1061.

[9]F. Zhang, C. Mihoc, F. Ahmed, C. Latte, E. Burkel. Thermal stability of carbon nanotubes, fullerene and graphite under spark plasma sintering. Chemical Physics Letters 510 (2011) 109-114

[10]F. Zhang, M. Adam, E. Otterstein, E. Burkel. Pulsed Electric Field Induced Diamond Synthesis from Carbon Nanotubes with Solvent Catalysts. Diamond and related Materials. 20 (2011) 853-858.

[11]A. Ibrahim，F. Zhang, E. Otterstein, E. Burkel. Processing of Porous Ti and Ti5Mn Foams by Spark Plasma sintering. Materials and Design. 2011, 32: 146-153.

[12]F. Zhang, J. Chang, E. Burkel. Dissolution Process and Mechanisms of Poly (Vinyl Alcohol) Modified Carbon Nanotubes. New Carbon Materials. 2010, 25(4): 1-7.

[13]F. Zhang, A. Weidmann, J. B. Nebe, U. Beck, E. Burkel. Preparation, Microstructures, Mechanical Properties and Cytocompatibility of TiMn Alloys for Biomedical Applications. Journal of Biomedical Materials Research B. 2010，94B: 406-413. 

[14]F. Zhang, E. Otterstein, E. Burkel. Spark plasma sintering, microstructures and mechanical properties of macroporous titanium foams. Advanced Engineering Materials. 2010, 12 (9): 863-872.

[15]F. Zhang, A. Weidmann, B. J. Nebe, E. Burkel. Preparation of TiMn alloy by mechanical alloying and spark plasma sintering for biomedical applications. Journal of Physics: Con. Series, 2009, 144:012007.

2005-2008 在中科院上海硅酸盐所的工作

[1]F. Zhang, J. Chang, J. Lu and C. Ning, Surface Modification of Beta-tricalcium Phosphate Scaffolds with Topological Nanoapatite Coatings. Materials Science and Engineering: C. 2009, 28(8): 1330-1339.

[2]Lihua Long, Faming Zhang, Lei Chen, Lidong Chen, Jiang Chang. Preparation and properties of β-CaSiO3/ZrO2 (3Y) nanocomposites. Journal of the European Ceramic Society, 2008, 28(15): 2883-2887.

[3]F. Zhang, J. Chang, K. Lin and J. Lu, Preparation, mechanical properties and in vitro degradability of wollastonite/tricalcium phosphate macroporous scaffolds from nanocomposite powders, Journal of Materials Science: Materials in Medicine 2008,19(1): 167-173.

[4]F. Zhang, K. Lin, J. Chang, J. Lu and C. Ning; Spark plasma sintering of macroporous calcium phosphate scaffolds from nanocrystalline powders. Journal of the European Ceramic Society, 2008, 28(3): 539-545.

[5]F. Zhang, J. Chang, J. Lu, K. Lin and C. Ning, Bioinspired structure of bioceramics for bone regeneration in load-bearing sites, Acta Biomaterialia, 2007, 3(6): 896-904.

[6]Faming Zhang, Jiang Chang, Jianxi Lu, Kaili Lin. Fabrication and Mechanical Properties of Dense/Porous β-Tricalcium Phosphate Bioceramics. Key Engineering Materials, Vols. 2007, 330-332: 907-910.

2000-2006年在哈工大读书期间

[1]F. Zhang, J. Shen, J. Sun, D.G. McCartney. Direct Synthesis of Diamond from Low Purity Carbon Nanotubes. Carbon. 44 (2006) 3136-3138.

[2]J. Shen, F. M. Zhang, J. F. Sun, Y. Q. Zhu and G. McCartney. Spark plasma sintering assisted Diamond Formation from Carbon Nanotubes at very Low Pressure. Nanotechnology. 17 (2006) 2187-2191.

[3]F. Zhang, J. Shen, J. Sun, Y. Q. Zhu, G. Wang and G.  McCartney. Conversion of Carbon Nanotubes to Diamond by a spark plasma sintering, Carbon. 2005, 43 (6): 1254-1258.

[4]Jun Shen, Faming Zhang, Jianfei Sun. Processing and Mechanical Properties of Spark Plasma Sintered WC-Co-Al2O3 Nanocomposites. Transactions of Nonferrous Metals Society of China. 2005.1:102-109.

[5]F. Zhang, J. Sun, J. Shen. Effects of Carbon Nanotubes Incorporation on the Grain growth of Nanocrystalline WC-Co cermets. Material Science Forum. 475-479 (2005): 989-992.

[6]F. Zhang, J. Shen, J. Sun. Processing and Properties of Carbon Nanotubes-Nano-WC-Co composites. Materials Science & Engineering A. 381（2004）91-96.

[7]F. Zhang, J. Shen, J. Sun. The Effect of Phosphorus additions on Densification, Grain growth and Properties of nanocrystalline WC/Co composites. Journal of Alloys and Compounds. 2004, 385(1-2): 96-103. 

[8]Jun Shen, Jianfei Sun and Faming Zhang. Synthesis and Characterizations of Nanocrystalline WC-Co Composite Powders by a Unique Ball Milling Process. Journal of Materials Science and Technology. 2004, 20(1): 7-10.

[9]J. Sun, F. Zhang, J. Shen. Characterization of ball-milled nanocrystalline WC-Co composite powders and subsequently rapid hot pressing sintered cermets. Materials Letters, 57(2003)3140-3148.

发明专利：

[1] 张法明，李萍，一种三维纳米多孔钛及其合金的制备方法，中国发明专利. CN201510158395.2。(授权).

[2] 张法明，刘苏丽，一种纳米金刚石增强钛基复合材料及其制备方法和应用,中国发明专利. CN201610302137.7 (授权).

[3] 赵佩佩，李萍，张法明，王利利. 一种钛或钛合金表面纳米多孔的制备方法, 中国发明专利. CN201610345100.7 (授权).

[4] 张法明，赵佩佩，刘腾飞一种原位合成纳米金刚石增强铁镍基复合材料的方法及其所得材料和应用.  中国发明专利. CN201710906498.1 （授权）

[5] 张法明，王娟.一种三维网络状分布的石墨烯增强钛基复合材料及其制备方法和应用.中国发明专利.CN201810801698.5 (授权)

[6] 范阔威，张法明. 一种纳米洋葱碳增强钛基复合材料及其制备方法. 中国发明专利.CN 201810946906.0 (授权)

[7] 张法明，杜茂龙. 一种Ti2AlC增强钛基复合材料及其制备方法和应用. 中国发明专利201811201329.0 (授权)。

[8] 张法明，范阔威，于金. 一种纳米洋葱碳多孔块体材料及其制备方法, 中国发明专利，201910598025.9 (已申请)

[9] 张法明，张彬，一种纳米TiC修饰石墨烯增强钛基复合材料及其制备方法和应用，中国发明专利，201910748096.2 (授权)

[10] 张法明，叶灿, 一种异构结构的钛基复合材料及其制备方法和应用，中国发明专利，202010818263.9(授权)

[11] 张法明，张瀚琳，万齐法. 一种表面复合硼化钛纤维的钛合金材料的制备方法和应用，中国发明专利 ZL 202111415817.1(授权)

[12]张法明，邓传迅，商彩云，熊义峰. 一种纳米洋葱碳复合磷酸铁锂的正极材料及其制备方法和应用,中国发明专利，202111413962.6 (授权)

[13]张法明，黄宜诺，熊义峰，一种3D打印微区梯度结构高熵合金钛合金复合材料及其制备方法和应用, 中国发明专利，202211259095.X (已授权).

[14]张法明，熊义峰.一种仿生结构的金属复合材料及其制备方法和应用, 中国发明专利202211259072.9 (已授权)

[15] 张法明，万齐法. 一种尖晶石结构高熵氧化物材料的制备方法和应用, 中国发明专利202410506737.4 (已申请)

[16] 张法明，冯蕙雅. 一种石墨烯修饰的高熵合金颗粒增强钛基复合材料及其制备方法和应用, 中国发明专利2024117891929 (已申请)

[17] 张法明，李柯汛. 一种双贯穿结构双金属复合材料及其制备方法和应用. 中国发明专利202610342478.5 (已申请)

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