【 Education Background】

1. Undergraduate Degree: University of Science and Technology Beijing

2. Doctoral degree: RWTH Aachen University, Germany

【 Work Experience】

1. 2018.12-2020.12 Assistant Researcher

2. 2021.01-Present Associate Research Fellow

【 Individual Resume】

Associate researcher, Chief Young Scientist of key projects of National Key Research Program, young scholar of North Science. At present, he is mainly engaged in the study of service damage behavior of advanced steel and superalloy. As the first author/corresponding author, he has published more than 30 Top papers in SCI academic journals at home and abroad. Including Materials Science & Engineering A, Journal of Materials Research & Technology, Materials Characterization, Engineering Fracture Mechanics and metal journal and other professional fields of famous journals, applied for 6 national invention patents. Presided over the national key research and development program, the National Natural Science Foundation, major national defense projects and cooperation projects with large and medium-sized enterprises.

【 Research Orientation】

1, aerospace high-temperature alloy strength and toughening design

2. Service damage behavior of gas turbine superalloy

3. Intelligent design and evaluation of advanced energy steel

【 Achievements】

【 Research Projects】

1. National Key Research and development plan key project, research on anti-fatigue high-crack non-homogeneous structure wind power steel, presided over

2. National Natural Science Foundation of China, Low Cycle fatigue damage mechanism of a novel γ 'phase strengthened cobalt based single crystal superalloy with low fault energy, hosted

3. Preresearch Project of National Defense Basic Scientific Research Program, ******, presided over

4. Participated in the key R&D plan of Guangdong Province, R&D and application demonstration of multi-scale full process preparation of superalloy

5. Dongfang Electric Turbine Co., LTD., Research on long-term static aging and creep microstructure evolution of gas turbine directionally solidified alloy MarM247LC, presided over

6. Central University basic scientific research business Fund for young talents Training, multi-scale organization and control of super austenitic stainless steel hot processing, presided over

7. Laigang, Research and application on welding fatigue performance mechanism of 420MPa grade wind power steel plate, participate

8. CGN, CGN-Beijing University of Science and Technology Joint Research and Development Center for Advanced Energy Materials and Service Safety, Science and technology cooperation services, participate

【 Academic Papers】

1. Rui Liu, Xitao Wang, Pinpin Hu, Chengbo Xiao, Jinshan He*, Low cycle fatigue behavior of micro-grain casting K4169 superalloy at room temperature, Progress in Natural Science: Materials International [J]., 2022, 32(6): 693-699

2. Yue Wang, Xitao Wang, Rui Liu, Pinpin Hu, Chengbo Xiao, Jinshan He*,Improved Tensile Properties of Micro-grain Casting K447A Alloy, Metallurgical and Materials Transactions A [J]., 2022

3. Shiguang Xu, Jinshan He*, Runze Zhang, Fucheng Zhang, Xitao Wang, Hot deformation behaviors and dynamic softening mechanisms of 7Mo super-austenitic stainless steel with high stacking fault energy, Journal of Materials Research and Technology [J]., 2023,23: 1738-1752

4. Runze Zhang, Jinshan He*, Shiguang Xu, Fucheng Zhang, Xitao Wang*, The roles of Ce and Mn on solidification behaviors and mechanical properties of 7Mo super austenitic stainless steel, Journal of Materials Research and Technology [J]., 2023,22: 1238-1249

5. Runze Zhang, Jinshan He*, Shiguang Xu, Yizhan Ma, Fucheng Zhang, Xitao Wang*, A σ phase-γ phase orientation relationship observed in solidification of the 7Mo super-austenitic stainless steel [J]., 2022, 21: 1248-1255

6. Bohao Ma,Xitao Wang,Gang Xu,Jinwu Xu andJinshan He *, Prediction of Creep Curves Based on Back Propagation Neural Networks for Superalloys, Materials[J], 2022, 15(19), 6523

7. Zhenhuan Gao, Yuhui Sun, Nan Liu, Xitao Wang, Jinshan He*, Role of stress on creep behaviors for MarM247LC DS superalloy, Fatigue & Fracture of Engineering Materials & Structures [J]., 2022

8. Jinshan He, Xuanlei Wang, Haijing Zhou, Xitao Wang, Low cycle fatigue of a γ’-strengthened Co-based single crystal superalloy at 900 °C, Materials Characterization [J]., 2022

9. Jinshan He, Xiaofei Guo*, Junhe Lian, Sebastian Münstermann, Wolfgang Bleck*, Delayed cracking behavior of a meta-stable austenitic stainless steel under bending condition, Materials Science & Engineering A[J]., 2019, 768:138470

10. Jinshan He, Zhengrong Yu, Longfei Li*, Xitao Wang, Qiang Feng, Effect of grit blasting and subsequent heat treatment on stress rupture property of a Ni based single crystal superalloy SGX3, Acta Metallurgica Sinica (English Letters) [J]., 2020,

11. Jinshan He, Zhengyin Piao, Xitao Wang*, Junhe Lian*, Sebastian Münstermann, Micromechanical modeling of cleavage fracture for a ferritic-pearlitic steel, Engineering Fracture Mechanics [J]., 2020, 186, 105–119

12. Jinshan He, Min Zou, Longfei Li*, Xitao Wang*, Qiang Feng, Creep behavior of a novel CoNi-base single-crystal superalloy at high temperature and low stress, Materials Letters[J]., 2020, 262:127042

13. Jinshan He, Junhe Lian*, Anke Aretz, Napat Vajragupta, Ude Hangen, Frank Goodwin, Sebastian Münstermann, Fracture properties of zinc coating layers in a galvannealed steel and an electrolytically galvanized steel, Materials Science & Engineering A [J]., 2018, 732: 320-325

14. Jinshan He, Junhe Lian*, Georg Golisch, An He, Yidu Di, Sebastian Münsterman, Investigation on micromechanism and stress state effects on cleavage fracture of ferritic-pearlitic steel at −196 °C, Materials Science & Engineering A [J]., 2017, 686: 134-141

15. Jinshan He, Junhe Lian*, Georg Golisch, Xiaodong Jie, Sebastian Münstermann, A generalized Orowan model for cleavage fracture, Engineering Fracture Mechanics[J].,2017, 186: 105–118

16. Jinshan He, Xitao Wang, Yang Zhang, Yameng Zhao, Hailong Zhang*, Thermal conductivity of Cu–Zr/diamond composites produced by high temperature–high pressure method, Composites: part B[J].,2015, 68: 22–26

17. Jinshan He; Hailong Zhang; Yang Zhang; Yameng Zhao; Xitao Wang*, Effect of boron addition on interface microstructure and thermal conductivity of Cu/diamond composites produced by high temperature-high pressure method, Physica Status Solidi A[J], 2014.03, 211(3):587~594.

【 Patents】

1. A low-carbon anti-fatigue wind power steel plate and its preparation method, 202111200081.6

2. A creep curve prediction method for Superalloys, 202210588091.X

3. Heat treatment process to eliminate σ phase in super austenitic stainless steel containing RE element, 202011235048.2

4. A multiphase composite high strength high toughness low density steel and a preparation method thereof, 202111620047.4

5. A corrosion-resistant high-strength light steel and a preparation method thereof, 202110065205.8

【 Honorary Title】

North Science young scholars,

International exchange program introduction project.