钛合金的强韧化和疲劳损伤、钛合金关键构件先进成型技术、金属3D打印

1. 2025年贵州省青年拔尖人才，2026.3-2030.3，50万元，主持，在研；

2. 贵州省第14批优青，2023.5-2026.4，20万元，主持，在研；

3. 国家自然科学基金地区基金项目：高强韧钛合金嵌套式梯度组织的扭转疲劳损伤机制研究，2023.1-2026.12，33万，主持，在研；

4. 国家自然科学基金地区基金项目：拉扭复合载荷下高强韧钛合金双态组织的形变损伤机制研究，2021.1-2024.12，35万，主持，结题；

5. 国家自然科学基金青年基金项目：高强韧钛合金多层次组织对缺口疲劳损伤行为的影响机理研究，2019.1-2021.12，24万，主持，结题；

6. 中国博士后基金面上项目：缺口参数和显微组织对高强韧钛合金疲劳损伤的协同影响机理研究，2020.11-2022.11，8万，主持，结题；

7. 贵州省科技支撑计划项目：无人机用高强韧钛合金扭力臂模锻成型关键技术研究与示范，2021.03-2023.12，450万，主持，结题；

8. 贵州省自然科学基金：显微组织和缺口参数对高强韧Ti-55531合金疲劳损伤的协同影响机理研究，2020.03-2023.03，10万，主持，结题。

9. 中国工程物理研究院，钛合金构件的疲劳性能测试及损伤机理分析，2025.06-2025.12，38.23万，主持，结题。

10. 卓普锐科技（重庆）有限公司，科技成果转化(专利许可)，2024.12-2025.12，20万，主持，结题。

[1] Xiaochuan Yang, Tianxin Li, Jiang Yang, Mingpan Wan, Zhong Zhang and Chaowen Huang*, Phase Boundary and Defect Dependent High Cycle Fatigue Behavior in Alcocrfeni2.1 Eutectic High-Entropy Alloy, International Journal of Fatigue, 2026, 206: 109462.

[2] Ji Huang, Zhong Zhang, Jiang Yang, Xin Wen, Dan Liu, Tianxin Li, Mingpan Wan, Junyu Chen, Chaowen Huang*, Ultrasonic Surface Rolling Improves Tensile Properties but Reduces Rotating Bending Fatigue Strength in a Titanium Alloy, Journal of Alloys and Compounds, 2026, 1057: 186824.

[3] Yanyan Zhao, Chaowen Huang*, Jiang Yang, Tianxin Li, Dan Liu, Junyu Chen, Mingpan Wan, Xing Ran, Gradient microstructure-mediated superior torsional properties in a metastable β Ti-55531 alloy. Journal of Alloys and Compounds, 2025. 1042: 183953.

[4] Xiang Li, Chaowen Huang*, Jiang Yang, Dan Liu, Tianxin Li, Changsheng Tan*, Weiju Jia*, Mingpan Wan, Effect of multilevel lamellar microstructures on notch high cycle fatigue damage micromechanism of TC21 alloy. International Journal of Fatigue, 2025. 199: 109013.

[5] Yanyan Zhao, Zhong Zhang, Chaowen Huang*, Jiang Yang, Changsheng Tan*, Mingpan Wan, Yongqing Zhao, Influence of multilevel lamellar microstructure on notch high cycle fatigue properties and crack initiation behavior of Ti-55531 alloy. Journal of Alloys and Compounds, 2025. 1010: 177684. (SCI 中科院2区，SCI他引4次)

[6] Xiang Li, Chaowen Huang*, Xianwei Ye, Jiang Yang, Mingpan Wan, Dan Liu, Effect of aging temperatures on the microstructure and mechanical properties of TC21 forgings with basket–weave microstructure. Materials Characterization, 2024, 216: 114270. (SCI 中科院1区，SCI他引11次)

[7] Kongliang Hu, Chaowen Huang*, Hongtao Zeng*, et al, Understanding deformation and fracture mechanism of Ti-55531 alloy under complex loading conditions: a case of pre-tensioned torsion, Rare Metals. 2024, 43(12):6673-6693. (SCI 中科院1区，SCI他引12次)

[8] Xiang Li, Chaowen Huang*, Jiang Yang, Fei Liu, Siyuan Wei, Mingpan Wan, Fei Zhao, Yongqing Zhao, Optimization of quasi-β forging parameters to control trimodal microstructure parameters and performance of TC21 forgings. Materials Science and Engineering: A, 2024,909:146824. (SCI 中科院1区，SCI他引11次)

[9] Changsheng Tan*, Tao Yang, Chaowen Huang*, Jiachen Zhang, Xueliang Wang, Hengping Lu, Linxian Wen, Guojun Zhang*, Enhanced strength–ductility synergy in Ti55531 titanium alloys through gradient microstructural design strategy. Materials Science and Engineering: A, 2024. 909, 146823. (SCI 中科院1区，SCI他引7次)

[10] Yiduo Fan, Changsheng Tan*, Chaowen Huang*, Jiahao He, Yan Pan, Linxian Wen, Hengping Lu, Guojun Zhang*, Strength and ductility improvement of the axial gradient microstructure TC21 titanium alloys manufactured by electropulsing plus step-quenching treatment. Journal of Alloys and Compounds, 2024. 984.173979. (SCI 中科院2区，SCI他引10次)

[11] Feiyu Huang, Chaowen Huang*, Hongtao Zeng*, Jiang Yang, Tao Wang, Mingpan Wan, Dan Liu, Shengli Ji, Weidong Zeng, Deformation and fracture mechanisms of Ti-55531 alloy with a bimodal microstructure under the pre-tension plus torsion composite loading, Journal of Materials Research and Technology, 2023, 26: 7425-7443. (SCI 中科院1区，SCI他引12次)

[12] Zhong Zhang, Chaowen Huang*, Zilu Xu, Jiang Yang, Shaolei Long, Changsheng Tan**, Mingpan Wan, Dan Liu, Shengli Ji, Weidong Zeng, Influence of Notch Root Radius On High Cycle Fatigue Properties and Fatigue Crack Initiation Behavior of Ti-55531 Alloy with a Multilevel Lamellar Microstructure, Journal of Materials Research and Technology, 2023, 24: 6293-6311. (SCI 中科院1区，SCI他引22次)

[13] Zilu Xu, Chaowen Huang*, Mingpan Wan*, Changsheng Tan, Yongqing Zhao, Shengli Ji, Weidong Zeng, Influence of Microstructure On Strain Controlled Low Cycle Fatigue Crack Initiation and Propagation of Ti-55531 Alloy, International Journal of Fatigue, 2022, 156：106678. (SCI 中科院1区，SCI他引39次)

[14] Zhong Zhang, Chaowen Huang*, Xin Wen, Mingpan Wan, Yongqing Zhao, Shengli Ji, Weidong Zeng, Synergistic Influence Mechanism of Microstructure Type and Loading Mode On the Long Crack Propagation in Ti-55531 Alloy, Engineering Fracture Mechanics, 2022, 266：108404.(SCI 中科院2区，SCI他引14次)

[15] Feiyu Huang, Chaowen Huang*, Mingpan Wan, Shewei Xin, Yongqing Zhao, Tao Wang, Shengli Ji, Weidong Zeng, Effect of Solution Temperature On Microstructure and Mechanical Properties of Ti–5Al5Mo5V3Cr1Zr Alloy, Advanced Engineering Materials, 2022：2200003.(SCI 中科院3区，SCI他引7次)

[16] Zhong Zhang, Chaowen Huang*, Sinuo Chen, Mingpan Wan, Ming Yang, Shengli Ji, Weidong Zeng, Effect of Microstructure On High Cycle Fatigue Behavior of 211Z.X-T6 Aluminum Alloy, Metals, 2022, 12(3)：387.(SCI 中科院3区，SCI他引6次)

[17] Zilu Xu, Chaowen Huang*, Changsheng Tan*, Mingpan Wan, Yongqing Zhao, Junqing Ye, Weidong Zeng. Influence of microstructure on cyclic deformation response and micromechanics of Ti–55531 alloy. Materials Science and Engineering: A, 2021, 803：140505.(SCI 中科院1区，SCI他引29次)

[18] Chaowen Huang*, Fengmei Wang, Xin Wen, Mingpan Wan, Min Lei, Junqin Ye, Weidong Zeng, Tensile Performance and Impact Toughness of Ti-55531 Alloy with Multilevel Lamellar Microstructure, Journal of Materials Science, 2021,56(14)：8848-8870.(SCI 中科院3区，SCI他引41次)

[19] Xin Wen, Mingpan Wan*, Chaowen Huang*, Min Lei. Strength and fracture toughness of TC21 alloy with multi-level lamellar microstructure. Materials Science and Engineering: A 2019;740-741:121-129. (SCI 中科院1区，SCI他引95次)

[20] Xin Wen, Mingpan Wan*, Chaowen Huang*, Min Lei.Yilong. Liang, Xin. Cai, Effect of microstructure on tensile properties, impact toughness and fracture toughness of TC21 alloy, Materials & Design, 180 (2019) 107898. (SCI 中科院1区, 他引137次)

[21] Chaowen Huang*, Yongqing Zhao*, Shewei Xin, Changsheng Tan, Wei Zhou, Qian Li, Weidong Zeng, Effect of microstructure on high cycle fatigue behavior of Ti-5Al-5Mo-5V-3Cr-1Zr titanium alloy. International Journal of Fatigue, 2017. 94: 30-40. (SCI 中科院1区, 他引95次)

[22] Chaowen Huang*, Yongqing Zhao*, Shewei Xin, Wei Zhou, Qian Li, Weidong Zeng, Effect of microstructure on tensile properties of Ti-5Al-5Mo-5V-3Cr-1Zr alloy. Journal of Alloys and Compounds, 2017. 693: 582-591. (SCI 中科院2区, 他引177次)

[23] Chaowen Huang*, Yongqing Zhao*, Shewei Xin, Changsheng Tan, Wei Zhou, Qian Li, Weidong Zeng, High cycle fatigue behavior of Ti-5Al-5Mo-5V-3Cr-1Zr titanium alloy with lamellar microstructure. Materials Science and Engineering: A, 2017. 682: 107-116. (SCI 中科院1区, 他引64次)

[24] Chaowen Huang*, Yongqing Zhao*, Shewei Xin, Wei Zhou, Qian Li, Weidong Zeng, Effect of microstructure on torsion properties of Ti-5Al-5Mo-5V-3Cr-1Zr alloy. Materials Science and Engineering: A, 2017. 682: 202-210. (SCI 中科院1区, 他引38次)

[25] Chaowen Huang*, Yongqing Zhao*, Shewei Xin, Wei Zhou, Qian Li, Weidong Zeng, Changsheng Tan, High cycle fatigue behavior of Ti-5Al-5Mo-5V-3Cr-1Zr titanium alloy with bimodal microstructure. Journal of Alloys and Compounds, 2017. 695: 1966-1975. (SCI 中科院2区, 他引69次)

部分授权专利：

(1). 黄朝文，万明攀，杨江等，一种用于金属圆柱形试样表面的电解抛光的方法及系统，中国发明专利：ZL202010217289.8；

(2). 黄朝文，万明攀，杨江等，一种激光进行金属材料深加工的方法，中国发明专利：ZL202010733033.2；

(3). Huang Chaowen, Wan Mingpan, Yang Jiang, et.al, METHOD AND SYSTEM FOR ELECTROLYTICALLY POLISHING SURFACE OF METAL CYLINDRICAL SPECIMEN, South Africa：2021/10630；

(4). 杨江，黄朝文，朱阮利等，一种金属材料生产加工用热处理装置，中国发明专利：ZL202010677147. X；

(5). 黄朝文，万明攀，杨江等，一种用于金属棒材批量加热的摆放台架，实用新型专利：ZL202020547679.7；

(6). 黄朝文，黄飞余，杨江，万明攀等，一种提高高强韧钛合金扭转疲劳性能的嵌套式梯度组织的制备方法，中国发明专利：ZL202210791320.8；

(7). 黄朝文，冀胜利，叶俊青，万明攀等，一种高强韧钛合金精密锻件模锻表面加工工艺，中国发明专利：ZL202111165228.2。

(8). Huang Chaowen, Yang Jiang, Wan Mingpan, et.al, PROCESSING METHOD FOR IMPROVING MACHINABILITY OF TITANIUM ALLOYS WITH HIGH-STRENGTH, Nederlands: 2031077.

科技奖励：

(1). 黄朝文，第十七届贵州省青年科技奖，2023.12.18，中共贵州省委组织部、贵州省人力资源与社会保障厅、贵州省科学技术协会；

(2). 梁益龙，母庚礼，梁宇，申曙光，李伟，龙见炳，黄朝文，唐义祥，王建军，高可靠长寿命精密传动齿轮系关键制造技术，贵州省科技进步一等奖，2021.12.23，贵州省人民政府；

(3). 赵飞，万明攀，袁慧，李伟，黄朝文. C250超高强度钢航空发动机关键轴零件热加工技术研究与应用，贵州省科技进步三等奖，2020.06.06，贵州省人民政府.

教学成果奖励：

(1). 2025年贵州大学教学名师；

(2). 2022年第十届贵州省高等教育教学成果奖一等奖1项，排第2；

(3). 2021年贵州大学本科教学成果奖 特等奖1项，排第2；

(4). 2021年贵州大学本科教学成果奖 一等奖1项，排第4。

国家自然科学基金通讯评审专家；全国研究生教育评估监测专家库专家；

中国材料研究学会疲劳分会第七届理事；中国机械工程学会热处理分会第九届青年委员会委员和材料分会第三届委员会委员；中国有色金属学会稀有金属材料第二届专委会委员；中国力学学会MTS材料试验协作专业委员会第二届委员；

《Rare Metals》、《中国有色金属学报（中、英文版）》、《材料工程》、《航空材料学院》、《失效分析与预防》和《贵州大学学报-自然科学版》青年编委；《Metals》客座编辑；

南洋理工大学(NTU)访问学者，贵州省优青、省青年拔尖人才、贵州大学学术学科带头人培育对象