专著、论文、专利及研究项目

1、 主编专著或教材：

[1] 李伟. 《Fatigue Design in Engineering》（ISBN: 978-7-5763-0864-8），北京理工大学出版社，2022年。

2、 代表性SCI论文（近5年）：

[1] Xiaolong Li, Wei Li*, Tianyi Hu, Shihua Yuan, Yucheng Zhang, Cheng Li, Liang Cai, Tatsuo Sakai, Muhammad Imran Lashari, Usama Hamid. A novel very-high-cycle-fatigue life prediction model with interior microstructure induced cracking behavior of Inconel-713C superalloy at 25 °C, 750 °C and 1000 °C. Theoretical and Applied Fracture Mechanics. 2023, 123: 103705. (IF=4.374)

[2] Cheng Li, Wei Li*, Shihua Yuan, Xiaolong Li, Liang Cai, Tianyi Hu, Zhenglin Mo, Muhammad Imran Lashari, Usama Hamid. High cycle and very high cycle fatigue properties and microscopic crack growth modeling of Ti-6.5Al-3.5Mo-1.5Zr-0.3Si titanium alloys at elevated temperatures. Fatigue & Fracture of Engineering Materials & Structures, 2022, 45: 3677-3691. (IF: 3.634) 2022.9.24

[3] Tianyi Hu, Wei Li*, Shihua Yuan, Yucheng Zhang, Xiaolong Li, Liang Cai, Zhenglin Mo, Cheng Li. Multiscale analysis of interior cracking behavior of Ni-based superalloy fabricated by selective laser melting under very-high-cycle-fatigue at high-temperature. Materials Today Communications, 2022, 33: 104356. (IF: 3.662) 2022.9.6

[4] Xiaolong Li, Wei Li*, Shihua Yuan, Tatsuo Sakai, Liang Cai, Yucheng Zhang, Cheng Li. Interior crystallographic plane induced cracking behavior of Ni-based superalloy in high-temperature and vacuum environment. Vacuum, 2022, 203: 111265.

[5] Yucheng Zhang, Xiaolong Li, Shihua Yuan, Rui Sun, Tatsuo Sakai, Muhammad Imran Lashari, Usama Hamid, Wei Li*. High-cycle-fatigue properties of selective-laser-melted AlSi10Mg with multiple building directions. International Journal of Mechanical Sciences, 2022, 224: 107336.

[6] Liang Cai, Wei Li*, Zhenglin Mo, Ping Wang, Muhammad Imran Lashari, Usama Hamid, Xiaoming Ding, Tatsuo Sakai, Tianyi Hu, Yucheng Zhang. In-situ experimental study of fatigue crack growth behavior for aluminum alloys under variable amplitude loading: Near-tip plasticity and crack closure evaluation. Theoretical and Applied Fracture Mechanics. 2022,119: 103372.

[7] Cheng Li, Wei Li*, Liang Cai, Yucheng Zhang, Rui Sun, Xiaolong Li, Muhammad Imran Lashari, Usama Hamid, Xiaoming Ding, Ping Wang. Microstructure based cracking behavior and life assessment of titanium alloy under very-high-cycle fatigue with elevated temperatures. International Journal of Fatigue, 2022, 161: 106914.

[8] Rui Sun, Wei Li*, Yucheng Zhang, Ping Wang, Tianyi Hu, Muhammad Imran Lashari, Wen Zhang. Interior long-life-fatigue cracking behavior and life prediction of a selective laser melted GH4169 superalloy at different temperatures and stress ratios. Fatigue & Fracture of Engineering Materials & Structures, 2022, 45: 13691.

[9] Xiaolong Li, Wei Li*, Muhammad Imran Lashari, Tatsuo Sakai, Ping Wang, Liang Cai, Xiaoming Ding, Usama Hamid. Fatigue failure behavior and strength prediction of nickel-based superalloy for turbine blade at elevated temperature. Engineering Failure Analysis, 2022, 136: 106191.

[10] Tianyi Hu, Rui Sun, Wei Li*, Tatsuo Sakai, Muhammad Imran Lashari, Ping Wang, Usama Hamid. Effect of treatment mode on microstructure evolution and mechanical properties of nickel-based superalloy fabricated by selective laser melting. Vacuum, 2022, 199: 110924.

[11] Xiaolong Li, Wei Li*, Muhammad Imran Lashari, Tatsuo Sakai, Ping Wang, Yucheng Zhang, Liang Cai, Usama Hamid, Xiaoming Ding. Elevated-temperature gigacycle fatigue properties of nickel based superalloy: Grain related cracking mechanism and life prediction modelling, Engineering Fracture Mechanics, 2022, 261: 108254.

[12] Cheng Li, Yucheng Zhang, Liang Cai, Tianyi Hu, Ping Wang, Xiaolong Li, Rui Sun, Wei Li*. A fatigue life prediction approach for interior cracking behavior of surface-carburized steels under high-cycle and very-high-cycle fatigue. Fatigue & Fracture of Engineering Materials & Structures, 2022, 45: 865-881.

[13] Liang Cai, Wei Li*, Tianyi Hu, Bin Ji, Yucheng Zhang, Tatsuo Sakai, Ping Wang. In-situ experimental investigation and prediction of fatigue crack growth for aluminum alloys under single overload. Engineering Fracture Mechanics, 2022, 260: 108195.

[14] Rui Sun, Wei Li*, Yucheng Zhang, Ping Wang*, Bin Ji, Tatsuo Sakai. Microstructure related failure mechanism of selective laser melted GH4169 with interior fatigue cracking, Materials letters, 2022, 308: 131284.

[15] Xiaolong Li, Yucheng Zhang, Wei Li*, Siqi Zhou, Ping Wang*. High-cycle and very-high-cycle-fatigue behavior and life prediction of Ni-based superalloy at elevated temperature. Fatigue & Fracture of Engineering Materials & Structures, 2021, 44: 3431-3447.

[16] Rui Sun, Wei Li*, Yucheng Zhang, TianYi Hu, Ping Wang*. Effect of solution treatment on high-temperature mechanical property of IN718 manufactured by selective laser melting. Journal of Materials Engineering and Performance, 2021, 30: 6821-6831.

[17] Xiaolong Li, Yucheng Zhang, Wei Li*, Siqi Zhou, Rui Sun, Cheng Li, Ping Wang*, Tatsuo Sakai. Very high cycle fatigue of a nickel-based superalloy at room and elevated temperatures: Interior failure behavior and life prediction. International Journal of Fatigue, 2021, 151: 106349.

[18] Wei Li*, Rui Sun, Tianyi Hu, Xiaolong Li, Cheng Li, Yucheng Zhang, Xiaoming Ding, Ping Wang*. Effect of elevated temperature on high-cycle and very-high-cycle fatigue properties of Ni-based superalloy manufactured by selective laser melting. International Journal of Fatigue, 2021, 148: 106250.

[19] Wei Li*, Rui Sun, Ping Wang*, Xiaolong Li, Yucheng Zhang, Tianyi Hu, Cheng Li, Tatsuo Sakai. Subsurface faceted cracking behavior of selective laser melting Ni-based superalloy under very high cycle fatigue. Scripta Materialia, 2021, 194: 113613.

[20] Wei Li*, Siqi Zhou, Xiaolong Li, Hailong Deng, Nehila Abdelhak, Ping Wang*, Tatsuo Sakai. Interior microscopic cracking behavior and microstructure-fatigue based damage evaluation of case-hardened steels under variable amplitude loading, Engineering Fracture Mechanics, 2020, 235: 107108.

[21] Wei Li*, Meng Li, Xinxin Xing, Ning Gao, Ping Wang. Faceted crack induced failure behavior and micro-crack growth based strength evaluation of titanium alloys under very high cycle fatigue. International Journal of Fatigue, 2020, 131: 105369.

[22] Wei Li*, Xinxin Xing, Ning Gao, Ping Wang. Subsurface crack nucleation and growth behavior and energy-based life prediction of a titanium alloy in high-cycle and very-high-cycle regimes. Engineering Fracture Mechanics, 2019, 221: 106705.

[23] Wei Li*, Xinxin Xing, Ning Gao, Meng Li, Rui Sun, Siqi Zhou, Tatsuo Sakai. Subsurface facets-induced crack nucleation behavior and microstructure-based strength evaluation of titanium alloys in ultra-long life regime. Materials Science and Engineering A, 2019, 761: 138055.

[24] Wei Li*, Rui Sun, Ning Gao, Ping Wang, Tatsuo Sakai. Interior induced fatigue of surface-strengthened steel under variable loading: Failure mechanism and damage modelling. Fatigue & Fracture of Engineering Materials & Structures, 2019, 42: 2383-2396.

[25] Ning Gao, Wei Li*, Rui Sun, Ping Wang, Tatsuo Sakai. A fatigue assessment approach involving small crack growth modelling for structural alloy steels with interior fracture behavior. Engineering Fracture Mechanics, 2018, 204(12): 198-210.

[26] Nehila Abdelhak, Wei Li*, Hongqiao Zhao, Ning Gao, Xinxin Xing. Very high cycle fatigue of surface carburized CrNi steel at variable stress ratio: Failure analysis and life prediction. International Journal of Fatigue, 2018, 111(6): 112-123.

[27] Nehila Abdelhak, Wei Li*, Hongqiao Zhao. Interior failure mechanism and life prediction of surface-treated 17CrNi steel under high and very high cycle fatigue. Fatigue & Fracture of Engineering Materials & Structures, 2018, 41(6): 1-12.

[28] Wei Li*, Ning Gao, Hongqiao Zhao, Xinxin Xing. Crack initiation and early growth behavior of TC4 titanium alloy under high cycle fatigue and very high cycle fatigue. Journal of Materials Research, 2018, 33(4): 935-945.

[29] Hailong Deng, Wei Li*, Hongqiao Zhao. Multiple fatigue failure behaviors and long-life prediction approach of carburized Cr-Ni steel with variable stress ratio. Materials, 2017, 10(9): 1084-1105.

[30] Wei Li*, Hongqiao Zhao, Nehila Abdelhak, Zhenyu Zhang, Tatsuo Sakai. Very high cycle fatigue of TC4 titanium alloy under variable stress ratio: Failure mechanism and life prediction. International Journal of Fatigue, 2017, 104(11): 342-354.

3、 发明专利：

[1] 李伟，邓海龙，孙振铎，张震宇. 基于缺口试件的啮合齿轮弯曲疲劳极限评估方法及装置，2017-5-17，中国，ZL201410539658.X。

[2] 李伟，邓海龙，孙振铎，张震宇. 表面梯度金属材料的细微观力学性能评估测量方法及装置，2017-1-4，中国，ZL201410599229.1。

[3] 李伟，刘鹏飞，邓海龙，赵虹桥. 恒变幅加载下机械结构的疲劳寿命可靠度评估方法及装置，2019-9-24，中国，ZL201710248956.7。

[4] 李伟，邓海龙，赵虹桥，刘鹏飞. 齿轮接触疲劳全寿命评估方法及装置，2019-4-23，中国, ZL201710200764.9。

[5] 李伟，赵虹桥，刘鹏飞，邓海龙. 齿轮弯曲疲劳寿命预测方法及装置，2020-4-3, 中国ZL201710197972.8。

[6] 李伟, 邢鑫鑫, 杲宁, 孙锐, 周思奇, 李萌. 一种涡轮增压器的多频疲劳试验方法, 2020-7-10, 中国，ZL201910133457.2。

[7] 李伟, 周思奇, 孙锐, 李萌, 李小龙. 一种考虑失效相关性的机械结构疲劳可靠性评估方法， 2020-11-3，中国，CN202010693359.7。

[8] 李伟, 周思奇, 孙锐, 李萌, 李小龙. 一种关于机械结构变幅疲劳寿命预测方法，2020-11-3，中国， CN202010694629.6。

[9] 李伟, 孙锐, 周思奇. 一种超高周疲劳寿命预测方法、装置及可存储介质，中国，202111006301.1。

4、 纵向研究项目（近5年）

1) 国家自然科学基金面上项目：激光选熔颗粒增强钛基纳米复合材料环境-超高周疲劳及逆向设计方法，2022/01-2024/12，58万，主持，在研；

2) 国家自然科学基金面上项目：涡轮叶片喷射成形高温合金的环境疲劳行为及超长寿命预测方法，2018/01-2021/12，63万，主持，结题；

3) 航天科学技术基金: 3D打印高强Al-Si-Mg合金环境致裂机理及超长寿命预测，2019/06-2020/06，8万，主持，在研；

4) 上海航天科技创新基金项目：3D打印Al-Si-Mg合金低温-超长寿命疲劳失效机制及寿命预测方法研究，2020/01-2021/12，10万，主持，在研；

5) 国家自然科学联合基金重点项目：基于载荷谱的电动汽车传动构件疲劳寿命与系统可靠性研究，2019/01-2022/12，210万，主持，在研（负责子课题）；

6) 国防基础产品创新科研项目：高原环境下xxx结构设计方法研究，2018/01-2020/12，280万，主持（负责子课题），结题；

7) 国防基础产品创新科研项目：XXX材料概率疲劳强度特性研究，2013/01-2017/12，460万，主持、结题；

8) 国家自然科学基金青年项目：涡轮增压器转轴渗氮钢的环境-缺陷致裂机理及超长寿命评估，2014/01-2017/12，25万，主持，结题；