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何超

(四川大學建築與環境學院教授)

鎖定
何超,男,教授,博導,四川省傑出青年基金、日本學術振興會JSPS外國人特別研究員項目獲得者 [1]  。致力於結構金屬材料及其焊接接頭超長壽命服役行為的研究工作,主持國家自然科學基金及省部級、橫向課題10餘項,獲2019年四川省科技進步一等獎、2022年教育部技術發明二等獎等。
中文名
何超
國    籍
中國
民    族
出生地
四川自貢
出生日期
1986年9月
畢業院校
四川大學
學位/學歷
博士
職    業
教師
專業方向
固體力學
職    務
教授、博導

目錄

  1. 1 經歷
  2. 2 研究領域
  3. 3 科研項目
  4. 4 代表論著

何超經歷

  • 2023~至今 四川大學 教授
  • 2019~2023 四川大學 特聘副研究員
  • 2016~2018 日本九州大學 JSPS研究員
  • 2015~2016 成都大學 特聘副研究員
  • 2014~2015 法國巴黎第十大學 聯合陪養博士
  • 2010~2015 四川大學 博士
  • 2006~2010 四川大學 學士

何超研究領域

  • 疲勞實驗技術、材料失效微納尺度表徵、焊接接頭長壽命服役行為、先進材料超長壽命疲勞、極端條件下材料力學行為等

何超科研項目

主持項目:
  • 國家自然科學基金面上項目,熱梯度條件下鎳基合金超長壽命疲勞-蠕變實驗及機制研究,2024.01-2027.12
  • 四川省傑出青年科學基金項目,先進增材製造材料超長壽命服役行為表徵與壽命預測,2023.01-2025.12
  • 國家自然科學基金面上項目,界面強化鎂合金長壽命疲勞小裂紋原子尺度失效機制研究,2021.01-2024.12
  • 四川省科技廳基礎研究項目,先進航空鈦合金超高周疲勞行為與失效的微納尺度機理,2021.04-2023.03
  • 國家自然科學基金青年項目,超長壽命區間高強鋁合金攪拌摩擦焊接頭顆粒物致裂機理研究及壽命預測,2017.1-2019.12
  • 特別研究員科研啓動金(日本學術振興會),LPSO相高強鎂合金超高周疲勞破壞機理解析,2016.11-2018.11
  • 日本Nanotech Japan若手研究項目,鎂合金疲勞滑移特徵的原子尺度解析,2017.12-2018.05
參與項目:
  • 1. 國家自然科學基金重點項目,微結構敏感超高周疲勞機理與超低速裂紋擴展研究,2019.01-2023.12
  • 2. 國家自然科學基金重大儀器研發專項,複雜載荷-環境下超長壽命疲勞振動加速綜合實驗系統研製,2014.01 -2018.12

何超代表論著

部分一作/通訊作者論文(截至2023年11月):
  1. XIANGYU WANG, CHAO HE, YAJUN DAI, CHANG LIU, MIN ZHAN, XUE LI, YONGJIE LIU, QINGYUAN WANG. Small fatigue crack growth in an extruded dual-phase Mg-Li alloy [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2023, 175: 107809.
  2. LI X, HE C, WANG X, CHEN Y, WANG C, ZHANG H, LI L, LIU Y, WANG Q. Effects of microstructure on crack initiation in super martensitic stainless steel under very‐high‐cycle fatigue at elevated temperature [J]. FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES, 2023, 46(3): 1060-77.
  3. WANG S, TANG S, HE C, WANG Q. Cyclic Deformation and Fatigue Failure Mechanisms of Thermoplastic Polyurethane in High Cycle Fatigue [J]. POLYMERS, 2023, 15(4): 899.
  4. ZHAN M, DAI Y, LIU C, WANG X, LI L, LIU Y, HE C, WANG Q. Effect of rolling on crack behavior of FeCrAl alloys in ultra-long life [J]. INTERNATIONAL JOURNAL OF STRUCTURAL INTEGRITY, 2023.
  5. DAI Y, WANG S, HE Q, LIU C, WANG X, LI X, LI L, LIU Y, HE C, WANG Q. Effect of microstructure on slip-induced crack initiation and early propagation of martensitic steel during high cycle fatigue [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2023, 167: 107275.
  6. FU L, LI X, LIN L, WANG Z, ZHANG Y, LUO Y, YAN S, HE C, WANG Q. Study on Microstructure Evolution Mechanism of Gradient Structure Surface of AA7075 Aluminum Alloy by Ultrasonic Surface Rolling Treatment [J]. MATERIALS, 2023, 16(16): 5616.
  7. WANG X, HE C, LI X, LIU Y, WANG Q, LI L, ZHANG H, WANG C. Crack initiation and propagation characteristics of a dual‐phase Mg–Li alloy under high‐cycle and very‐high‐cycle fatigue regimes [J]. FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES, 2022, 45(1): 84-100.
  8. MENG D, YANG S, HE C, WANG H, LV Z, GUO Y, NIE P. Multidisciplinary design optimization of engineering systems under uncertainty: a review [J]. INTERNATIONAL JOURNAL OF STRUCTURAL INTEGRITY, 2022, 13(4): 565-93.
  9. LIU H, SONG J, WANG H, YU C, DU Y, HE C, WANG Q, CHEN Q. Slip-driven and weld pore assisted fatigue crack nucleation in electron beam welded TC17 titanium alloy joint [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2022, 154: 106525.
  10. LI X, DAI Y, WANG X, LIU Y, CHEN Y, WANG C, ZHANG H, LI L, LIU H, HE C. Effects of local microstructure on crack initiation in super martensitic stainless steel under very-high-cycle fatigue [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2022, 163: 107019.
  11. DAI Y, LIU C, ZHAN M, WANG X, HE C, WANG Q. Heterogeneous deformation of friction stir welded aluminum alloy 6061 in tension and high cycle fatigue [J]. INTERNATIONAL JOURNAL OF STRUCTURAL INTEGRITY, 2022, 13(5): 813-28.
  12. CHEN Z, DONG Z, LIU C, DAI Y, HE C. Characterization on Crack Initiation and Early Propagation Region of Nickel-Based Alloys in Very High Cycle Fatigue [J]. MATERIALS, 2022, 15(17): 5806.
  13. WANG X, HE C, LI X, LIU Y, WANG Q, ZHANG H, LI L, WANG C. Crack initiation and propagation mechanisms of an extruded dual-phase Magnesium-Lithium alloy in very high cycle fatigue regime [J]. 2021.
  14. MENG D, LI Y, HE C, GUO J, LV Z, WU P. Multidisciplinary design for structural integrity using a collaborative optimization method based on adaptive surrogate modelling [J]. MATERIALS & DESIGN, 2021, 206: 109789.
  15. HE C, LI X, LIU Y, WANG C, ZHANG H, LI L, WANG Q, SHAO X, CHEN Q. Localized dislocation interactions within slip bands and crack initiation in Mg-10Gd-3Y-0.3 Zr alloy [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2021, 150: 106302.
  16. LI X, ZHANG R, WANG X, LIU Y, WANG C, ZHANG H, LI L, HE C, WANG Q. Effect of high temperature on crack initiation of super austenitic stainless steel 654SMO in very high cycle fatigue [J]. MATERIALS & DESIGN, 2020, 193: 108750.
  17. HE C, WU Y, PENG L, SU N, CHEN Q, YUAN S, LIU Y, WANG Q. Effect of microstructure on small fatigue crack initiation and early propagation behavior in Mg-10Gd-3Y-0.3 Zr alloy [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2019, 119: 311-9.
  18. HE C, SHAO X, YUAN S, PENG L, WU Y, WANG Q, CHEN Q. Small crack initiation and early propagation in an as-extruded Mg-10Gd-3Y-0.5 Zr alloy in high cycle fatigue regime [J]. Materials Science and Engineering: A, 2019, 744: 716-23.
  19. HE C, WU Y, PENG L, SU N, LI X, YANG K, LIU Y, YUAN S, TIAN R. Cyclic deformation and correspondent crack initiation at low-stress amplitudes in Mg–Gd–Y–Zr alloy [J]. MATERIALS, 2018, 11(12): 2429.
  20. HE C, LIU Y, LI J, YANG K, WANG Q, CHEN Q. Very-high-cycle fatigue crack initiation and propagation behaviours of magnesium alloy ZK60 [J]. Materials Science and Technology, 2018, 34(6): 639-47.
  21. [21] HE C, YANG K, LIU Y, WANG Q, CAI M. Improvement of very high cycle fatigue properties in an AA7075 friction stir welded joint by ultrasonic peening treatment [J]. FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES, 2017, 40(3): 460-8.
  22. HE C, KITAMURA K, YANG K, LIU Y-J, WANG Q-Y, CHEN Q. Very high cycle fatigue crack initiation mechanism in nugget zone of AA 7075 friction stir welded joint [J]. Advances in Materials Science and Engineering, 2017, 2017.
  23. HE C, LIU Y, DONG J, WANG Q, WAGNER D, BATHIAS C. Through thickness property variations in friction stir welded AA6061 joint fatigued in very high cycle fatigue regime [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2016, 82: 379-86.
  24. HE C, TIAN R-H, LIU Y-J, LI J-K, WANG Q-Y. Ultrasonic fatigue damage behavior of 304L austenitic stainless steel based on micro-plasticity and heat dissipation [J]. Journal of Iron and Steel Research International, 2015, 22(7): 638-44.
  25. HE C, LIU Y, DONG J, WANG Q, WAGNER D, BATHIAS C. Fatigue crack initiation behaviors throughout friction stir welded joints in AA7075-T6 in ultrasonic fatigue [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2015, 81: 171-8.
  26. HE C, HUANG C, LIU Y, LI J, WANG Q. Effects of mechanical heterogeneity on the tensile and fatigue behaviours in a laser-arc hybrid welded aluminium alloy joint [J]. Materials & Design (1980-2015), 2015, 65: 289-96.
  27. HE C, HUANG C, LIU Y, WANG Q. Fatigue damage evaluation of low-alloy steel welded joints in fusion zone and heat affected zone based on frequency response changes in gigacycle fatigue [J]. INTERNATIONAL JOURNAL OF FATIGUE, 2014, 61: 297-303.
  28. 何超, 崔仕明, 劉永傑, 王清遠. 氣孔對鋁合金焊接接頭超長疲勞壽命的影響 [J]. 焊接學報, 2014, 35(11): 18-22.
  29. HE C, LIU Y, FANG D, WANG Q. Very high cycle fatigue behavior of bridge steel welded joint [J]. Theoretical and Applied Mechanics Letters, 2012, 2(3): 031010.
  30. 何超, 王清遠, 劉永傑. 超聲加載條件下低合金鋼疲勞裂紋擴展壽命 [J]. 四川大學學報: 工程科學版, 2012, (S2): 23-6.
參考資料
  • 1.    何超簡介  .四川大學建築與環境學院—官網[引用日期2024-03-07]