研究方向

极端环境金属燃烧与特种材料设计：

（1）极端服役环境下金属燃烧行为与机理

（2）极端服役环境用抗燃涂层与工程化应用

（3）极端服役环境用高温高强特殊钢与工程化应用

教育经历

2009/09-2013/07 合肥工业大学 金属材料与工程 工学学士

2013/09-2014/07 北京科技大学 材料科学与工程 工学硕士

2014/09-2019/07 北京科技大学 材料科学与工程 工学博士

2019/10-2021/12 北京科技大学 新金属材料全国重点实验室 博士后

2022/01 至今 北京科技大学 新金属材料全国重点实验室 助理研究员

学术兼职

Journal of Alloy and Compounds, Journal of Materials Research and Technology, Defence Technology等学术期刊审稿人。

研究项目

（1）国家自然科学基金委员会, 青年科学基金项目（C类）, 52101072, 基于原位拉曼光谱的钛合金起燃特征与微观机理研究, 结题, 负责人。

（2）某预研关键技术，*****冷阻燃防钛火设计与验证技术，结题，负责人

（3）吴运铎创新中心，**内膛表面材料组织与力学性能研究，结题，负责人

（4）某专项，****新材料工程化应用，在研，参加。

论文著作

[1] Zhang C*, Wang Y, Li J, Zu Z, Wang W, He G, Wang C*, Huang J. The influence of α/β phase constitution on the combustion behavior of TC25G alloy under oxygen-enriched atmosphere. Journal of Materials Research and Technology, 2026, 41:5630.

[2] Li J, Wang Y, Wang C, Wang S, Wang W, Jin P, Zu Z, Zhang Y, He G, Zhang C*, Huang J*. Unveiling the critical conditions for ignition and flame-retardant mechanisms of NiCrAl/YSZ coatings applied for protection of titanium alloys. Corrosion Science, 2026, 260:113566.

[3] Zhang Y, Zha X, Feng K, Li Y, Li J, Hu J, Zu Z, Zhang C, Wang C, Dou C, Huang J*, Zhang C*. Oxidation and crack propagation in the TC4 titanium alloy under high-speed transient impact-rubbing leading to Pre-Ignition. Engineering Failure Analysis, 2026, 186:110455.

[4] Zhang R, Shao L*, Song Q, Wang C, Ma M, Huang J, Zhang C*. Effect of TiN/CrN coatings on the oxidation and combustion behavior of Ti64 alloy: Microstructural evolution and performance optimization. Journal of Alloys and Compounds, 2026, 1059.

[5] Wang X, Zu Z, Li Y, Li J, Huang J, Zhang C*, Shao L*. Comparative Study of Combustion Behavior and Mechanism of 1060 and 7075 Aluminum Alloys. Journal of Alloys and Compounds, 2025, 1035: 181629.

[6] Li J, Xing P, Wang C, Jin P, Li Y, Zhang Y, Wang Y, He G, Zhang C*, Huang J*. Unveiling the Dependence of Laser Energy on Ignition Critical Conditions in TC11 Titanium Alloy under High Temperature Airflow. Journal of Alloys and Compounds, 2025, 1040: 183622.

[7] Wang C, Li J, Li Y, Jin P, Yu S, Wu Y, He G, Huang J*, Zhang C*. Effect of grain boundary on the ignition and flame propagation mechanisms of TC11 alloy in oxygen-enriched environment, Corrosion Science, 2024, 237：112291-112303.

[8] Wang C, Li J, Li Y, He G, Huang J*, Zhang C*. Ignition and flame propagation behaviors of titanium alloys in oxygen-enriched atmospheres. Journal of Materials Research and Technology, 2025, 34: 35-47.

[9] Zhang C*, Wang Y, Xue J, Li J, Wang S, Jin P, Shi X, Zhang C, Dou C, Chen J, Huang J. Investigating the thermal-chemical-mechanical coupling effects on the cracking behavior of machine gun barrel: Microstructural insights. Materials Characterization, 2024, 218: 114522-114532.

[10] Dou C, Jin P, Wang C, Li J, Zhang C, Huang J*, Zhang C*. The Kirkendall effect on erosion resistance of chrome-coated 25Cr3Mo2WNiV and 30SiMn2MoV gun barrel steels, Journal of Materials Science & Technology, 2023, 177: 246-255.

[11] Chen J, Jia Z, Wang J, Jin P, Cao Y, Zhao C, Dou C, Li R, Zhang C*; Huang J*. Newly developed high-strength martensitic stainless steel for the sniper rifle barrel with high shooting accuracy, Journal of Materials Research and Technology, 2023, 24: 3956-3968.

[12] Zhang C*; Cao Y, Chen J, Ye H, Zhao C, Huang J. Microstructure stabilities of newly developed hot‐working die steel and H13 steel at elevated temperature, Steel Research International, 2023, 94: 2200811-2200822.

[13] Wang C, Li Z, Dou C, Jiao Y, Li J, He G, Song X, Zhang C*, Huang J*. A Theoretical Description of the Ignition Conditions for TC17 Alloy in Oxygen-Enriched Atmospheres. Combust Sci Technol 2023, 196: 3559–3575.

[14] Dou C, Su B, Wang C, Jin P, Chen J, Huang J*, Zhang C*. A comparative study on gunpowder erosion and promoted ignition combustion of 30SiMn2MoV gun barrel, Engineering Failure Analysis, 2022, 142: 106741-106741.

[15] Chen J, Wang W, Jin P, Dou C, Zhao C, Li Q, Zhang C*, Huang J*. Thermo-mechanical analysis of strength degradation of 30SiMn2MoVA gun barrel material during continuous shooting. Engineering Failure Analysis, 2022;139: 106438.

[16] Zhang Z, Zhang J, Lian Y, Ma M, Zhao C, Ye H, Li G, Zhang C*, Huang J*. Effects of vanadium content on the carbides transformation and strengthening mechanism of MPS700V hot-work die steel at room and elevated temperatures. Materials Science & Engineering A, 2021;813:141091.

[17] Zhang C, Wu Y*, You L, Qiu W, Zhang Y, Yuan Y, Lu Z, Song X. Nanoscale phase separation of TiZrNbTa high entropy alloy induced by hydrogen absorption. Scripta Materialia, 2020, 178:503–7.

[18] Zhang C, Song A, Yuan Y, Wu Y, Zhang P, Lu Z, Song X*. Study on the hydrogen storage properties of a TiZrNbTa high entropy alloy. International Journal of Hydrogen Energy, 2020, 45: 5367–74.

[19] Zhang C, Wu Y, You L, Cao X, Lu Z, Song X*. Investigation on the activation mechanism of hydrogen absorption in TiZrNbTa high entropy alloy. Journal of Alloys and Compounds, 2019, 781:613–20.

[20] Zhang C, Yang Y, Zhang Y, Liu J, You L, Song X*. Precipitation of cotunnite-type zirconia induced by deuterium absorption in Zr-4 alloy. Scripta Materialia, 2018, 143:1–4.

专      利

1. 张诚; 黄进峰; 汪从珍; 李志斌; 何光宇; 一种金属燃烧起燃条件的预测方法, 2025-04-04, 中国, CN202210619221.1

2. 张诚; 何康; 黄进峰; 王凤平; 汪从珍; 李志斌; 原位测试金属燃烧敏感性特征的方法及系统, 2022-06-21, 中国, CN202110969668.7

3. 张诚; 黄进峰; 汪从珍; 原位测试金属微区燃烧特征的方法, 2022-06-01, 中国, CN202211033319.5

4. 张诚; 李建军; 黄进峰; 何光宇; 王标; 抗燃可磨耗复合涂层的确定方法及抗燃可磨耗复合涂层, 2024-06-26, 中国, CN202410835060.9