Associate Professor Department of Mechanical and Energy Engineering
Dr. Shuai Wang received his Doctor degree from Hokkaido University, Japan, in 2013. After graduation, he became WPI postdoctoral researcher at International Institute of Carbon-Neutral Energy Research (WPI-I2CNER) in Kyushu University, Japan. From 2015 to 2018, he worked as an associate researcher at University of Wisconsin-Madison, USA. He joined Southern University of Technology and Science of China in 2018.
Personal Profile
Shuai Wang
Associate Professor
Research Areas: Multiscale Mechanic of Materials
Email: wangs<AT>sustech.edu.cn
Group website: http://faculty.sustech.edu.cn/profiles/wangs/
Address: Department of Mechanical and Energy Engineering, Southern University of Science and Technology, 1088 Xueyuan Blvd, Shenzhen 518055, China
Dr. Shuai Wang joined the Department of Mechanical and Energy Engineering at Southern University of Science and Technology as an Assistant Professor in June 2018. He received his Doctor degree from Hokkaido University, Japan, in 2013. After graduation, he became WPI postdoctoral researcher in International Institute of Carbon Neutral Energy Research (WPI-I2CNER) in Kyushu University, Japan. From 2015 to 2018, he worked as an associate researcher at University of Wisconsin-Madison, USA. He attended key projects related to the research of defects behavior and mechanical property of new energy material that sponsored by the Japanese Ministry of Education, National Science Foundation in the USA, and Department of Energy in the USA. In 2017, he has been nominated to become a WPI Visiting Faculty in I2CNER. He is the author of one textbook and more than 30 research papers.
Research Interest:
By using electron transmission microscopy and atomistic simulation as main approaches, his group focus their research on mechanical behavior and microstructure evolution of materials in nano- and micro-scale, to enhance the understanding of the underlying mechanisms for the strengthening and failure process, and formulate physic model for the selection and design of stronger and safer new materials, which is the most needed tool for the new energy society.
Education:
- 2010-2013 Ph.D. (Material Science), Hokkaido University
- 2007-2010 M.Eng. (Materials Physics and Chemistry), University of Science and Technology Beijing
- 2003-2007 B.Eng. (Metallic Materials Engineering), HeFei University of Technology
Research experience:
- 2020.01-Present Associate Professor, Southern University of Science and Technology
- 2018.06-2020.12 Assistant Professor, Southern University of Science and Technology
- 2015.04-2018.06 Research associate, University of Wisconsin-Madison
- 2014.04-2015.03 Postdoctoral researcher, International Institute for Carbon-Neutral Energy Research
- 2013.12-2014.03 Technical Assistant, Hokkaido University
Publication Highlights:
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Qingqing Sun, Yong Ni, and Shuai Wang*. Orientation Dependence of Dislocation Structure in Surface Grain of Pure Copper Deformed in Tension.Acta Materialia 203: 116474;2020.
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Shuai Wang*, Kelly E Nygren, Akihide Nagao, Petros Sofronis, and Ian M Robertson. "On the Failure of Surface Damage to Assess the Hydrogen-Enhanced Deformation Ahead of Crack Tip in a Cyclically Loaded Austenitic Stainless Steel. Scripta Materialia 166: 102-06;2019.
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Shuai Wang*, Akihide Nagao, Petros Sofronis, and Ian M Robertson. "Assessment of the Impact of Hydrogen on the Stress Developed Ahead of a Fatigue Crack. Acta Materialia 174 : 181-88;2019.
Shuai Wang*, Akihide Nagao, Petros Sofronis, and Ian M. Robertson*; Hydrogen-modified dislocation structures in a cyclically deformed ferritic-pearlitic low carbon steel; Acta Materialia; 144,164-176; 2018
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Shuai Wang*, Akihide Nagao, Kaveh Edalati, Zenji Horita, and Ian M. Robertson*; Influence of hydrogen on dislocation self-organization in Ni; Acta Materialia; 135, 96–102; 2017
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Shuai Wang, May L. Martin, Ian M. Robertson*, and Petros Sofronis; Effect of hydrogen environment on the separation of Fe grain boundaries; Acta Materialia; 107, 279–288; 2016
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Shuai Wang, May L. Martin, Petros Sofronis, Somei Ohnuki, Naoyuki Hashimoto, and Ian M. Robertson*; Hydrogen-induced intergranular failure of iron; Acta Materialia; 69, 275282; 2014
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Shuai Wang*, Naoyuki Hashimoto, Yongming Wang, and Somei Ohnuki; Activation volume and density of mobile dislocations in hydrogen charged Fe; Acta Materialia; 61 (13), 47344742; 2013
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Kelly E. Nygren, Shuai Wang, Kaila M. Bertsch, Hongbin Bei, Akihide Nagao, Ian M. Robertson*; Hydrogen embrittlement of the equi-molar FeNiCoCr alloy; Acta Materialia;157, 218–227; 2018
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K. E. Nygren, K. M. Bertsch, S. Wang, H. Bei, A. Nagao,I. M. Robertson*; Hydrogen embrittlement in compositionally complex FeNiCoCrMn FCC solid solution alloy; Current Opinion in Solid State and Materials Science; 22-1, 1-7; 2018
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Mo-Rigen He*, Shuai Wang, Shi Shi, Ke Jin, Hongbin Bei, Kazuhiro Yasuda, Syo Matsumura, Kenji Higashida, and Ian M. Robertson*;Mechanisms of radiation-induced segregation in CrFeCoNi-based single-phase concentrated solid solution alloys; Acta Materialia; 126, 182–193; 2017
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Shuai Wang*, Naoyuki Hashimoto, and Somei Ohnuki;Hydrogen-induced change in core structures of 110[111] edge and 110[111] screw dislocations in iron; Scientific Reports; 3, Article number: 2760; 2013
Research
By using electron transmission microscopy and atomistic simulation as main approaches, his group focus their research on mechanical behavior and microstructure evolution of materials in nano- and micro-scale, to enhance the understanding of the underlying mechanisms for the strengthening and failure process, and formulate a physic model for the selection and design of stronger and safer new materials, which is the most needed tool for the new energy society, and devoted to the performance and safety of key component materials for aerospace, hydrogen energy, and nuclear reactor systems.
Teaching
Engineering Materials - Science, Technology and Design
Microstructure Characterization and Analysis
Publications Read More
By using electron transmission microscopy and atomistic simulation as main approaches, his group focus their research on mechanical behavior and microstructure evolution of materials in nano- and micro-scale, to enhance the understanding of the underlying mechanisms for the strengthening and failure process, and formulate a physic model for the selection and design of stronger and safer new materials, which is the most needed tool for the new energy society. Our recently published research papers are listed as follows:
1. Q. Sun, Y. Ni, S. Wang*, Orientation dependence of dislocation structure in surface grain of pure copper deformed in tension, Acta Materialia 203 (2021) 116474.
2. S. Wang*, A. Nagao, P. Sofronis, I.M. Robertson*, Assessment of the impact of hydrogen on the stress developed ahead of a fatigue crack, Acta Materialia 174 (2019) 181-188.
3. S. Wang*, A. Nagao, P. Sofronis, I. M. Robertson*, Hydrogen-modified dislocation structures in a cyclically deformed ferritic-pearlitic low carbon steel, Acta Materialia 144 (2018) 164-176.
4. S. Wang, A. Nagao, K. Edalati, Z. Horita, I.M. Robertson, Influence of hydrogen on dislocation self-organization in Ni, Acta Materialia 135 (2017) 96-102.
5. S. Wang, M.L. Martin, I.M. Robertson, P. Sofronis, Effect of hydrogen environment on the separation of Fe grain boundaries, Acta Materialia 107 (2016) 279-288.
6. S. Wang, M.L. Martin, P. Sofronis, S. Ohnuki, N. Hashimoto, I.M. Robertson, Hydrogen-induced intergranular failure of iron, Acta Materialia 69 (2014) 275-282.
7. S. Wang*, N. Hashimoto, Y. Wang, S. Ohnuki, Activation volume and density of mobile dislocations in hydrogen-charged iron, Acta Materialia 61(13) (2013) 4734-4742.
8. M.-R. He, S. Wang, S. Shi, K. Jin, H. Bei, K. Yasuda, S. Matsumura, K. Higashida, I.M. Robertson, Mechanisms of radiation-induced segregation in CrFeCoNi-based single-phase concentrated solid solution alloys, Acta Materialia 126 (2017) 182-193.
9. M.L. Martin, M. Dadfarnia, A. Nagao, S. Wang, P. Sofronis, Enumeration of the hydrogen-enhanced localized plasticity mechanism for hydrogen embrittlement in structural materials, Acta Materialia 165 (2019) 734-750.
10. K.E. Nygren, K.M. Bertsch, S. Wang, H. Bei, A. Nagao, I.M. Robertson, Hydrogen embrittlement in compositionally complex FeNiCoCrMn FCC solid solution alloy, Current Opinion in Solid State and Materials Science 22(1) (2018) 1-7.
11. T. Ma, S. Wang, M. Chen, R.V. Maligal-Ganesh, L.-L. Wang, D.D. Johnson, M.J. Kramer, W. Huang, L. Zhou, Toward Phase and Catalysis Control: Tracking the Formation of Intermetallic Nanoparticles at Atomic Scale, Chem 5(5) (2019) 1235-1247.
12. J. He, Z. Zeng, H. Li, S. Wang*, The microstructure and mechanical properties of copper in electrically assisted tension, Materials & Design 196 (2020).
13. H. Li, J. He, Q. Sun, S. Wang*, Effect of the environment on the morphology of Ni powder during high-energy ball milling, Materials Today Communications 25 (2020) 101288.
14. S. Wang *, K.E. Nygren, A. Nagao, P. Sofronis, I.M. Robertson, On the failure of surface damage to assess the hydrogen-enhanced deformation ahead of crack tip in a cyclically loaded austenitic stainless steel, Scripta Materialia 166 (2019) 102-106.
15. Q. Sun, Q. Han, S. Wang *, R. Xu, Microstructure, corrosion behaviour and thermal stability of AA 7150 after ultrasonic shot peening, Surface and Coatings Technology 398 (2020) 126127.
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Email: wangs@sustech.edu.cn
Group website: http://faculty.sustech.edu.cn/wangs/
Address: Department of Mechanical and Energy Engineering, Southern University of Science and Technology, 1088 Xueyuan Blvd, Shenzhen 518055, China