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] Faming Zhang, Eberhard Burkel, Gunnar Rott. Verfahren zur Synthese von Diamanten. Deutsches Patent, DE 10 2011 014 204 A1.(授权).

主要的SCI学术论文：

2025

[1]Qifa Wan, Faming Zhang*, Yifeng Xiong. High-entropy engineering enables spinel oxides toward high-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 lattice structure with B4C/AlSi10Mg interpenetrating phases. Composites Part A,188(2025)108579  （Q1）

2024

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

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

[5]   Qifa Wan, Faming Zhang*, Yifeng Xiong. Facile synthesis, characterization, and mechanical properties of spinel-structured high-entropy oxides: Lattice distortion and sluggish diffusion effects induced by aluminum cation. Journal of the European Ceramic Society 44 (2024) 6629-6640（Q1）

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

2023

[7] Caiyun Shang, Faming Zhang*, Yifeng Xiong, Qifa Wan, FengChen. Spark plasma forging and network size effect on strength-ductility trade-off in graphene reinforced Ti6Al4V matrix nanocomposites. Materials Science and Engineering: A, 2023, 862:144480

[8] Qifa Wan, Faming Zhang *, Yifeng Xiong, Caiyun Shang. Formation, thermal stability, and infrared radiation properties of spinel-structured high-entropy oxides in Co–Mn–Fe–Cr–Ni–Zn–O system. Ceramics International, 2023, 08, 228.

2022

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

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

[11]Caiyun Shang, Faming Zhang *, Juan Wang, Feng Chen. Interface configuration effect on mechanical and tribological properties of three-dimension network architectural titanium alloy matrix nanocomposites. Composites: Part A 158 (2022) 106981

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

[13]Yifeng Xiong, Faming Zhang*, Yinuo Huang, Caiyun Shang, Qifa Wan. Multiple strengthening via high-entropy alloy particle addition in titanium matrix composites fabricated by spark plasma sintering. Materials Science & Engineering A 859 (2022) 144235

[14]Yifeng Xiong, Faming Zhang*, Ting Dai, Caiyun Shang, Qifa Wan. Crystal growth mechanism and mechanical properties of Ti-6Al-4V alloy during selective laser melting. Materials Characterization 194 (2022) 112455

2021

[15]Yifeng Xiong, Maolong Du, Faming Zhang*, Farhad Saba, Caiyun Shang.Preparation and mechanical properties of titanium alloy matrix composites reinforced by Ti3AlC and TiC ceramic particulates. Journal of Alloys and Compounds 886 (2021) 161216.

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

[17]Farhad Saba, Behzad Nateq, Seyed Abdolkarim Sajjadi, Faming Zhang, Simin Heydari.The enhanced mechanical properties and strain-hardening capability of CNT/Al composites achieved by heterogeneous micro-laminated architecture. Composites Communications 27 (2021) 100861

[18]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

[19]Faming Zhang, Kuowei Fan, Farhad Saba, Jin Yu. Graphene reinforced-graphitized nanodiamonds matrix composites:Fabrication, microstructure, mechanical properties, thermal and electrical conductivity. Carbon, 169(2020)416-428.

[20]Caiyun Shang, Faming Zhang, Bin Zhang, Feng Chen. Interface microstructure and strengthening mechanisms of multilayer graphene reinforced titanium alloy matrix nanocomposites with network architectures. Materials and Design, 2020, https://doi.org/10.1016/j.matdes.2020.109119

[21]Caiyun Shang, Tengfei Liu, Faming Zhang, Feng Chen. Effect of network size on mechanical properties and wear resistance of titanium/nanodiamonds nanocomposites with network architecture. Composites Communications, 19 (2020) 74–81.

[22]Kuowei Fan, Faming Zhang, Caiyun Shang, Farhad Saba, Jin Yu. Mechanical properties and strengthening mechanisms of titanium matrix nanocomposites reinforced with onion-like carbons. Composites Part A, 132 (2020) 105834.

[23]Farhad Saba, Elham Garmroudi-Nezhad, Faming Zhang, Lili Wang. Fabrication, mechanical property and in vitro bioactivity of hierarchical macro-/micro-/nano-porous titanium and titanium molybdenum alloys. Journal of Materials Research, 2020,doi:10.1557/jmr.2020.12

[24]Faming Zhang, Juan Wang, Tengfei Liu, Caiyun Shang. Enhanced mechanical properties of few-layer graphene reinforced titanium alloy matrix nanocomposites with a network architecture. Materials and Design, 186 (2020) 108330.

[25]Faming Zhang, Maolong Du, Kuowei Fan, Can Ye, Bin Zhang. Fabrication and mechanical properties of network structured titanium alloy matrix composites reinforced with Ti2AlC particulates. Materials Science & Engineering A, 776 (2020) 139065.

[26]Tao Wen, Kuowei Fan, Faming Zhang. High strength and high ductility in nickel matrix nanocomposites reinforced by carbon nanotubes and onion-like-carbon hybrid reinforcements. Journal of Alloys and Compounds, 814 (2020) 152303.

[27]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.

[28]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

[29]Faming Zhang, Kuowei Fan, Jin Yu, Farhad Saba and Jing Sun. Pulsed direct current field-induced thermal stability and phase transformation of nanodiamonds to carbon onions. RSC Adv., 2019, 9, 14360

[30]Farhad Saba, Faming Zhang, Suli Liu, Tengfei Liu. Reinforcement size dependence of mechanical properties and strengthening mechanisms in diamond reinforced titanium metal matrix composites, Composites B. 2019, 167:7-19.

[31]Faming Zhang, Tengfei Liu. Nanodiamonds reinforced titanium matrix nanocomposites with network architecture. Composites B. 2019, 165:143-154.

2018

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

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

[34]Faming Zhang, Peipei Zhao, Teifei Liu, Suli Liu, Zhang Peigen, Jin Yu, Jing Sun. In-situ synthesis of nanodiamonds reinforced iron-nickel matrix nanocomposites and their properties. Diamond and related Materials. 2018, 83:60-66.

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

[36]Farhad Saba, Seyed Abdolkarim Sajjadi, Mohsen Haddad-Sabzevar, Faming Zhang. TiC-modified carbon nanotubes, TiC nanotubes and TiC nanorods: Synthesis and characterization. Ceramics International. 2018, 44:7949-7954.

2017

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

[38]Faming Zhang, Ping Li, Jin Yu et al. Fabrication, formation mechanism and properties of three-dimensional nanoporous titanium dealloyed in metallic powders. Journal of Materials Research 2017, 32(8)1528-40.

[39]Faming Zhang, Lili Wang, Ping Li, Suli Liu, Peipei Zhao, Ge Dai and Siyuan He. Preparation of Nano to Submicro-Porous TiMo Foams by Spark Plasma Sintering. Advanced Engineering Materials, 2017, 19(2):1-10. 

[40]Farhad Saba， Seyed A. Sajjadi，Mohsen Haddad-Sabzevar, Faming Zhang. Formation mechanism of nano titanium carbide on multi-walled carbon nanotube and influence of the nanocarbides on the load-bearing contribution of the nanotubes inner-walls in aluminum-matrix composites. Carbon, 2017, 115C: 720-729.

2016

[41]Farhad Saba， Faming Zhang，Seyed A. Sajjadi，Mohsen Haddad-Sabzevar，Ping Li，Pulsed current field assisted surface modification of carbon nanotubes with nanocrystalline titanium carbide，Carbon，2016，101：261-271.

[42]Faming Zhang，Ping Li，Ge Dai，Siyuan He，Fabrication and properties of three-dimensional nanoporous graphene foams with magnesium binder，Scripta Materialia，2016，111：89-93.