1、教育学习经历：

2008/09-2012/06   东北大学       冶金工程           本科

2012/09-2014/07   东北大学        材料学            硕士

2014/09-2018/04   东北大学        材料学            博士

2、研究工作经历：

2018/04-2020/12 中国科学院金属研究所/材料使役行为研究部   助理研究员

2019/05-2022/08 中国科学院金属研究所/材料使役行为研究部    博士后

2020/12-2024/10 中国科学院金属研究所/材料使役行为研究部    副研究员

2024/10至今    中国科学院金属研究所/材料使役行为研究部    项目研究员

钢铁材料及其构件疲劳性能优化及可靠性评价。

研究工作简介：

      以“钢铁材料及构件疲劳性能优化及可靠性评价”为主要研究方向，立足疲劳基础理论研究，以优化材料/构件疲劳性能、解决关键构件服役可靠性问题为目标。在基础研究方面，构建了金属材料高周疲劳强度以及疲劳裂纹扩展速率预测与优化模型，发展了缺口疲劳强度修正模型、疲劳强度应力比修正模型，为材料/构件抗疲劳设计奠定理论基础。在工程应用方面，将上述理论应用于关键构件服役性能优化与评价，如优化汽车板簧疲劳寿命、汽车扭力梁疲劳寿命及飞轮转子疲劳寿命与评价风机轮毂服役寿命等。相关成果在Mater. Sci. Eng. A、J. Mater. Sci. Technol.、Int. J. Fatigue等国内外期刊上发表学术论文40余篇，累计被引用460余次；获得授权专利8项。

      作为项目负责人承担国家自然科学青年基金项目1项、吉林省与中国科学院科技合作高技术产业化专项1项、中国科学院金属研究所创新基金培育项目1项、博士后面上资助项目1项、企业横向课题6项，作为项目任务负责人参与国家科技重大专项1项，作为项目执行负责人参与德阳市科技“揭榜挂帅”重大攻关项目1项、“钒钛联盟”项目1项，作为项目核心成员参与中国科学院先导专项2项、国家自然科学基金项目2项、吉林省与中国科学院科技合作高技术产业化专项1项、企业横向课题2项。

1. 博士研究生国家奖学金. 2015.

2. 东北大学优秀博士毕业论文. 2019.

3. 沈阳市自然科学学术成果二等奖. 2020.

4. 金属研究所“2021年度（首届）青年学者论坛”二等奖. 2021.

1、Wang B#*,Pan Q W,Xu Z K,Zhang P*,Yan Y,Gu X Z,Li Y,Hong C,Li X W,Zhang Z F*. Investigation on the fatigue crack growth behaviors of AISI 4340 steel with different strength-toughness combinations. Advanced Engineering Materials,2024,26(6):2301692.

2、Wang B#*,Tian Z J,Qin J Y,Xu Z K,Zhang P*,Shi F,Gu X Z,Li X W,Zhang Z F*. Investigation on the fatigue behaviors of maraging steel at different stress ratios. Advanced Engineering Materials,2023,25(19):2300712.

3、Wang B#,Duan Q Q,Zhang P*,Zhang Z J,Li X W,Zhang Z F*. Investigation on the cracking resistances of different ageing treated 18Ni maraging steels. Materials Science and Engineering A,2020,771: 138553.

4、Wang B#,Zhang P*,Liu R,Duan Q Q,Zhang Z J,Li X W,Zhang Z F*. An optimization criterion for fatigue strength of metallic materials. Materials Science and Engineering A,2018,736: 105-110.

5、Wang B#,Zhang P*,Duan Q Q,Zhang Z J,Yang H J,Pang J C,Tian Y Z,Li X W,Zhang Z F*. Synchronously improved fatigue strength and fatigue crack growth resistance in twinning-induced plasticity steels. Materials Science and Engineering A,2018,711: 533-542.

6、Wang B#,Zhang P*,Duan Q Q,Zhang Z J,Yang H J,Li X W,Zhang Z F*. Optimizing the fatigue strength of 18Ni maraging steel through ageing treatment. Materials Science and Engineering A,2017,707: 674-688.

7、Wang B#,Zhang P*,Duan Q Q,Zhang Z J,Yang H J,Pang J C,Tian Y Z,Li X W,Zhang Z F*. High-cycle fatigue properties and damage mechanisms of pre-strained Fe-30Mn-0.9C twinning-induced. Materials Science and Engineering A,2017,679: 258-271.

8、Wang B#,Zhang Z J,Shao C W,Duan Q Q,Pang J C,Yang H J,Li X W,Zhang Z F*. Improving the high-cycle fatigue lives of Fe-30Mn-0.9C twinning-induced plasticity steel through pre-straining. Metallurgical and Materials Transactions A,2015,46: 258-271.

9、Wang B#,Duan Q Q,Yao G,Pang J C,Zhang Z F,Wang L,Li X W*. Fatigue fracture behaviour of spot welded B1500HS steel under tensile-shear load. Fatigue and Fracture of Engineering Materials and Structures,2015,38: 914-922.

10、Wang B#,Duan Q Q,Yao G,Pang J C,Li X W,Wang L,Zhang Z F*. Investigation on fatigue fracture behaviors of spot welded Q&P980 steel. International Journal of Fatigue,2014,66: 20-28.

11、程亚军#,高占朋,薛宁鑫,王斌*,段启强,白鑫. 5083铝合金焊接接头高周疲劳行为研究. 热加工工艺,2023,07: 12-15+11.

12、程亚军#,冷利,宫柏山,王科飞,白鑫,张鹏,王斌*. 时效时间对7075铝合金疲劳裂纹扩展速率的影响. 材料热处理学报,2021,42(05):26-31.

13、潘权文#,颜莹,李小武,王斌*,张鹏,张哲峰. 热处理对双真空冶炼AISI 4340钢显微组织和拉伸性能的影响. 材料热处理学报,2021,42(04):87-95.

14、李瑞#,马恒,周相海,钱苗,钱科,王斌*,张鹏. 平均应力对6.8级螺栓材料的高周疲劳行为的影响. 材料热处理学报,2019,40(04):62-67.

15、Qi Z#,Wang B,Zhang P*,Liu R,Zhang Z J,Zhang Z F*. Different effects of multiscale microstructure on fatigue crack growth path and rate in selective laser melted Ti6Al4V. Fatigue and Fracture of Engineering Materials and Structures,2022,45(9):2457-2467.

16、戚钊#,王斌,张鹏*,刘睿,张振军,张哲峰*. 应力比对含缺陷选区激光熔化TC4合金稳态疲劳裂纹扩展速率的影响. 金属学报,2022,DOI 10.11900/0412.1961.2022.00154. 

17、Xia B#,Wang B,Zhang P*,Ren C X,Duan Q Q,Li X W*,Zhang Z F*. Improving the high-cycle fatigue life of a high-strength spring steel for automobiles by suitable shot peening and heat treatment. International Journal of Fatigue,2022,161: 106891.

18、Liu S#,Wang B,Zhang P*,Bai X,Duan Q Q,Wang X G,Zhang Z F*. The Effect of Microstructure Inhomogeneity on Fatigue Property of EA4T Axle Steel. Steel Research International,2022,93(9):2200179.

19、Wang P#,Wang B,Liu Y,Zhang P*,Luan Y K,Li D Z,Zhang Z F*. Effects of inclusion types on the high-cycle fatigue properties of high-strength steel. Scripta Materialia,2022,206: 114232.

20、Lu S L#,Zhang Z J*,Liu R,Qu Z,Wang B,Zhou X H,Eckert J,Zhang Z F*. Prior beta grain evolution and phase transformation of selective laser melted Ti6Al4V alloy during heat treatment. Journal of Alloys and Compounds,2022,914: 165235.

21、Xie Z M#,Wang P,Wang B,Zhang P*,Bai X,Zhang Z F*. Effects of Heat Treatment on Fatigue Properties of Double Vacuum Smelting High-Carbon Chromium-Bearing Steel. Advanced Engineering Materials,2022,24(10):2200151.

22、Li H F,Zhang P,Wang B,Zhang Z F. Predictive fatigue crack growth law of high-strength steels. Journal of Materials Science and Technology,2022,100: 46-50.

23、Li H F#,Duan Q Q,Zhang P*,Zhou X H,Wang B,Zhang Z F*. The quantitative relationship between fracture toughness and impact toughness in high-strength steels. Engineering Fracture Mechanics,2019,211: 362-370.

24、Xia B#,Zhang P*,Wang B,Zhu Y K,Li X W*,Zhang Z F*. A simultaneous improvement of the strength and plasticity of spring steels by replacing Mo with Si. Materials Science and Engineering A,2021,820: 141516.

25、Xu Z K#,Wang B,Zhang P*,Zhang Z F*. Short fatigue crack growth behavior in 18Ni marageing steel. Materials Science and Engineering A,2021,807: 140844.

26、Xu Z K#, Wang B,Zhang P*,Zhang Z F*. A fast evaluation method for fatigue strength of maraging steel: The minimum strength principle. Materials Science and Engineering A,2020,789: 139659.

27、Liu R#,Zhang P*,Wang B,Zhang Z. J,and Zhang Z F*. A practical model for efficient anti-fatigue design and selection of metallic materials: I. Model building and fatigue strength prediction,Journal of Materials Science and Technology,2021,70: 233-249.

主要专利情况：

1、赵吉中,王斌,张鹏,朱艳坤,张哲峰,伏培林,阚前华. 一种循环载荷作用下金属结构接触的安定分析方法,授权时间:2024-01-02,中国,ZL202010862357.6.（授权）

2、张鹏,王鹏,王斌,庞建超,张哲峰. 一种估算高强钢疲劳失效临界夹杂物尺寸的方法,授权日期:2022-03-08,中国,ZL202011236998.7.（授权）

3、张鹏,许自宽,王斌,周相海,段启强,张哲峰. 一种通过拉伸试验预测金属材料疲劳强度的方法,授权日期:2021-07-16,中国,ZL201911150020.6.（授权）

4、张鹏,许自宽,王斌,段启强,张哲峰. 一种细长金属材料拉伸试样的制备方法,授权日期:2021-06-11,中国,ZL201911148965.4.（授权）

5、张哲峰,王斌,张鹏,刘睿,庞建超,段启强. 一种通过拉伸性能确定金属材料疲劳强度的方法,授权日期:2021-06-01,中国,ZL201711237807.7.（授权）

6、张鹏,许自宽,王斌,段启强,张哲峰. 一种轴向加载高周疲劳裂纹萌生寿命的测量方法,授权日期:2020-11-24,中国,ZL201810985004.8.（授权）