Email:shenyf@smm.neu.edu.cn
主要研究方向:
1. 高性能超细晶/纳米结构金属材料制备及塑性行为;2.高熵合金的微观组织及变形机理;3. 金属材料微观组织演变、断裂失效的实验表征或数值模拟
相关成果在《Science》,《Science Advances》、《Acta Materialias》,《International Journal of Plasticity》、《Materials Future》、《Journal of Materials and Science Technology》等国际著名材料期刊上发表论文100余篇,被SCI期刊引用9500余次,超过100次引用的文章17篇,单篇最高引次3000余次。
获得国家科技进步一等奖1项,辽宁省科技一等奖1项,山东省科技二等奖1项,山西省自然科学二等奖1项,日内瓦国际博览会金、银奖各1项。
H-指数: 43 论文引次:9500余次
论文链接:
https://webofscience.clarivate.cn/wos/author/record/ABI-4583-2020
https://www.scopus.com/authid/detail.uri?authorId=55575612800
学术兼职:
1. 教育部学位与研究生教育评估专家;2. 教育部全国本科毕业设计抽检评审专家;3. 学术桥评审专家;4. 凡科评审质量研究院优秀评审专家
5. 辽宁/甘肃/四川/江西/广东/安徽/山西/内蒙古/河北/省科技评审专家
6. 辽宁省金属学会理事/轧钢分会副主任委员
7. 沈阳市领军人才;8. 无锡市太湖人才
9. 国际SCI期刊《Nanomaterials》特邀编委
承担或参与的主要科研项目
(1) 国家自然科学基金项目(No:U2330110),01/2024.1-12/2026,项目负责人/ 46万
(2) 国家自然科学基金项目(No:51574079),01/2015-12/2018,项目负责人/ 75.6万
(3) 国家自然科学基金项目(No:U1430132)01/2014-12/2016,项目负责人/ 80万
(4) 国家重点实验室开放课题项目,10/2015/10-09/2017,项目负责人/ 10万
(5) 国家重点实验室开放课题(201201):06/2012 – 06/2014,项目负责人/11万
(6) 中央高校基本科研业务费专项资金资助项目(N090402007): 03/2014 – 03/2016,项目负责人/15万
(7) 横向课题, 2021/4-2022/2, 项目负责人/ 43.3万 (宝钢)
(8) 横向课题,2019/1-2020/11,项目负责人/24.7万(中国物理研究院)
(9) 横向课题,2018/1-2020/12,项目负责人/ 80万。
(10) 国家自然科学基金重点项目(No:51231002): 01/2013-12/2017,金属材料复杂服役条件下三维多尺度应力场演化与损伤机制关联性研究,排名第5/290万
(11) 国家科技支撑计划项目(No:2011BAE13B03): 01/2011-12/2014,排名第3/420万
(12) 国家自然科学基金青年项目(No:51001024)01/2012-12/2015“镍钛铌记忆合金微观力学行为演化机理的原位衍射研究”, 排名第2/20万
(13) 国家自然科学基金重点项目(No:50431010)超高强纳米金属及其强化机制, 01/2005-12/2008, 排名第3/160 万
(14) 国家自然科学基金项目(No:50201017)温度和变形速率对块状纳米晶Cu变形机理的影响,01/2003-12/2005,排名第2/ 29 万
(15) 国家自然科学基金项目(No:50571096)孪晶界及层错对纳米晶体铜加工硬化行为的影响,01/2006-12/2008,排名第2/32 万
主要荣誉和获奖情况:
(1)2024:山西省自然科学二等奖,(总排序3/4,校内排序:唯一),剪切/震动耦合超常动态凝固理论与方法,山西省政府
(2)2022:山东省科学技术二等奖,特高压输电塔用高强高韧Q420系列角钢的开放和工业化实施,山东省政府
(3)2018:辽宁省自然科学学术成果一等奖
(4)2018:沈阳市领军人才
(5)2017:东北大学“方大奖教金”二等奖
(6)2017:无锡市“太湖人才计划”2017年度产业升级创新领军人才
(7)2017:中国有色金属科技论文一等奖(排名第1),中国有色金属学会, 2017/11/06
(8)2017:冶金科学技术二等奖(排名第8),连续流变扩展挤压短流程制备高性能金属材料,中国钢铁工业协会,中国金属学会
(9)2016: 日内 瓦国际发明专利博览会-金奖, 连续流变扩展挤压+ACEF短流程制备高性能超细晶铝合金电工铝材
(10)2016: 日内瓦国际发明专利博览会-银奖,剪切振动耦合作用下高性能金属半固态流变挤压铸造
(11)2014: 辽宁省自然科学一等奖 ,金属材料的纳米孪晶强化,辽宁省科技厅
(12)2012:国家科技进步一等奖,中华人民共和国国务院
(13)2011:辽宁省自然科学学术成果特等奖,应用于废水净化的尺寸及结构可控的纳米Fe3O4粒子,
指导学生获奖:
Ø 2023:本科生李德宏获得“2023届东北大学优秀毕业论文” – 指导教师
Ø2021:研究生王竟获得“2020年辽宁省优秀硕士论文” – 指导教师
Ø 2020:研究生王竟获得“2020年东北大学优秀硕士论文” – 指导教师
Ø 2019:研究生梁佳伟获得“2019年辽宁省优秀硕士论文” – 指导教师
Ø 2018:研究生梁佳伟获得“2018届东北大学优秀硕士论文” – 指导教师
Ø 2017:本科生周亚星获得“2017届东北大学优秀毕业论文” – 指导教师
Ø 2015:研究生邱丽娜获得“2015届东北大学优秀硕士论文” – 指导教师
Ø 2012:研究生邱从怀获得“2012届东北大学优秀硕士论文” – 指导教师
Ø2009:研究生唐坚获得“2009年辽宁省优秀硕士论文” – 指导教师
国内外学术会议特邀报告 (15次):
[1] TMS 2025 Annual Meeting & Exhibition (Invited speaker):Ultrahigh Strength Triggered by BCC and B2 EutecticPhase Interfaces in a Novel Fe30Cr15V15Ni20Al20 High Entropy Alloy,Las Vegas, USA;2025/03/22-26
[2] 先进钢铁材料分会特邀报告: 低碳超高强度舰船用钢组织及性能调控. 2025 先进金属材料及成形加工技术研讨会,江苏-南京;2025/04/11-13
[3] 6th Advanced materials science world congress (Invited speaker): Controllable selection of martensitic variant enables concurrent enhancement of strength and ductility in a low-carbon steel, Amsterdam, Netherlands; 2024/03/21-22
[4] E01分会特邀报告 (Invited speaker): 细晶、超细晶高强度钢在纳米压痕下的微观力学行为. 2021中国材料大会,福建-厦门;2021/7/08-12
[5] TEM/APT表征新一代先进高强度钢铁材料,2020年全国电子显微学学术年会--先进显微分析技术在工业材料中的应用分会(特邀报告),四川-成都,2020.11.21-25
[6] 6th International Congress on Microscopy & Spectroscopy (INTERM) (Invited speaker): Interesting microstructural features of ultrahigh strength steel characterized by SEM/EBSD/TEM, Oludeniz, Turkey; 2019/05/12-18
[7] E01分会特邀报告 (Invited speaker): 金属的纳米结构强化. 2018中国材料大会,福建-厦门;2018/7/12-16
[8] Global Congress & Expo on Materials Science & Nanoscience (Invited speaker): Nanoscale plate-shaped precipitates strengthened Lanthanum-bearing Mg-3Sn-1Mn alloys through continuous rheo-rolling,Dubai, UAE;2016/10/24-26
[9] 2016 Nanomaterials workshop (Invited speaker): Ultra-Fine Grained Al/Mg Alloys Strengthened by Nanosized Precipitates using Continuous Rheo Extending Extrusion,江苏-南京;2016/06/06-08
[10] 先进钢铁材料分会特邀报告(Invited speaker): 孪生诱导塑性钢的研究进展—实验、模拟与趋势. 第十四届全国青年材料科学技术研讨会,辽宁-沈阳;2013/10/17-20
[11] THERMEC’ 2013 (Invited speaker): Improved ductility of a transformation-induced-plasticity steel by nanoscale bainite lamellae using quenching & partitioning process,Las Vegas, USA;2013/12/02-06
[12] 超细晶分会特邀报告 (Invited speaker): 连续轧制法制备的超细晶304SS不锈钢及其力学性能. 2012中国材料大会,山西-太原;2012/7/13-18.
Publications:
More than 130 original journal publications (including top ranking journals such as 《Science》,《Science Advances》、《Acta Materialias》,《International Journal of Plasticity》,《Journal of Materials and Science Technology》,《Scripta Materials》,《Material Science and Engineering A》, etc.), The total citations are over 8300 so far. Delivered more than 10 plenary/invited presentations at conferences/symposia.
Publications link:https://www.scopus.com/authid/detail.uri?authorId=55575612800
Publications list:
[1] L. Lu, Y.F. Shen, X.H. Chen, L.H. Qian, K. Lu, Ultrahigh strength and high electrical conductivity in copper. Science, 304 (2004) 422-426. [2] Y.F. Shen, L. Lu, Q.H. Lu, Z.H. Jin, K. Lu, Tensile properties of copper with nano-scale twins. Scripta Mater., 52 (2005) 989–994. [3] Y.F. Shen, L. Lu, M. Dao, S. Suresh, Strain rate sensitivity of copper with nano-scale twins. Scripta Mater., 55 (2006) 319-322. [4] M. Dao, L. Lu, Y.F. Shen, S. Suresh, Strength, strain-rate sensitivity and ductility of Cu with nano-scale twins. Acta Mater., 54 (2006) 5421-5432. [5] Y.F. Shen*, W.Y. Xue. Recovery palladium, gold and platinum from hydrochloric acid solution using 2-hydroxy-4-sec-octanoyl diphenyl-ketoxime, Sep. Pu ri. Technol., 56 (2007) 278–283. [6] Y.F. Shen*, W.Y. Xue, Y.D. Wang, Y.D. Liu, L. Zuo, Tensile behaviors of IF steel with different cold-rolling reductions. Mater. Sci. Eng. A, 496 (2008) 383–388. [7] Y.F. Shen*, W.Y. Xue, W. Li, Y.L. Tang, Selective recovery of nickel and cobalt from cobalt-enriched Ni–Cu matte by two-stage counter-current leaching. Sep. Puri. Technol., 60 (2008) 113–119. [8] Y.L. Yang , N. Jia, Y.D. Wang, Y.F. Shen, H. Choo, P.K. Liaw, Simulations of texture evolution in heavily deformed bulk nano-crystalline nickel. Mater. Sci. Eng. A, 493 (2008) 86–92. [9] Y.F. Shen*, W.Y. Xue, Y.D. Wang, Z.Y. Liu, L. Zuo, Mechanical properties of nano-crystalline nickel films deposited by pulse plating. Surf. Coat. Technol., 202 (2008) 5140–5145. [10] Y.F. Shen*, J. Tang, Z.H. Nie, Y.D. Wang, Y. Ren, L. Zuo, Preparation and application of magnetic Fe3O4 nanoparticles for waste water purification. Sep. Puri. Technol., 68 (2009) 312-319. [11] L. Lu, T. Zhu, Y.F. Shen, M. Dao, K. Lu, S. Suresh, Stress relaxation and the structure size-dependence of plastic deformation in nanotwinned copper. Acta Mater., 57 (2009) 5165-5173. [12] Y.F. Shen*, J. Tang, Z.H. Nie, Y.D. Wang, Y. Ren, L. Zuo. Tailoring size and structural distortion of Fe3O4 nanoparticles for the purification of contaminated water. Bioresou. Technol., 100 (2009) 4139-4146. [13] Y.F. Shen*, Sun X., X.P. Liu, Y.D. Wang, R.L. Pen, L. Zuo, Twinning during the tensile deformation of a TWIP steel. TMS2010, Seattle, USA, 02/14-19/2010. [14] Y.F. Shen*, W.Y. Xue, Y.H. Guo, Effect of cold rolling and annealing on texture evolution and mechanical properties of IF steel sheet. Steel Res. Int., 81(2010)146-149. [15] Y.F. Shen*, W.Y. Xue, Z.Y. Liu, L. Zuo, Nanoscratching deformation and fracture toughness of electroless Ni–P coatings. Surf. Coat. Technol., 205(2010)632-640. [16] Y.D. Wang, W.J. Liu, L. Lu, Y.F. Shen, et al., Low temperature deformation detwinning- a reverse mode of twinning. Adv. Eng. Mater., 12(2010) 901-911. [17] A. Soulami, K.S. Choi, Y.F. Shen, W.N. Liu, X. Sun, M.A. Khaleel, On deformation twinning in a 17.5% Mn-TWIP steel: A physically based phenomenological model. Mater. Sci. Eng. A, 528 (2011) 1402-1408. [18] R.L. Peng, X.P. Liu, Y.D. Wang, Y.F. Shen, S. Johansson, In-situ neutron diffraction study of the deformation behavior of two high-manganese austenitic steels. Mater. Sci. Forum 681 (2011) 474-479. [19] Y.F. Shen*, X. Sun, C.M. Wang, A micro-alloyed ferritic steel strengthened by nanoscale precipitates. Mater. Sci. Eng. A, 528 (2011) 8150 - 8156. [20] Y.F. Shen*, X.X. Li, X. Sun, Y.D. Wang, L. Zuo. Twinning and martensite in a 304 austenitic stainless steel, Mater Sci Eng A, 552(2012) 514-522. [21] Y.F. Shen*, W. N. Liu, X. Sun, W.Y. Xue, Y.D. Wang, L. Zuo, and P. K. Liaw, Plastic deformation in an amorphous Ni-P coating. Metall. Mater. Trans. A, 43 (2012) 1610-1620. [22] Y.F. Shen*, S.L. Chen, W.Y. Xue, Z.Y. Liu, R.X. Zhang, Y.D. Liu, Tensile properties of a Fe-20Mn-3Si-3Al-0.045C Steel at different strain rates and various temperatures. Steel Res. Int., (2012) 1179-1182. [23] Y.F. Shen*, Y.D. Wang, X.P. Liu, X. Sun, R. Lin Peng, S.Y. Zhang, L. Zuo, P.K. Liaw, Deformation mechanisms of a 20Mn TWIP steel investigated by in situ neutron diffraction and TEM, Acta Mater., 61(2013) 6093-6106. [24] Y.F. Shen*, Y.D. Liu, X. Sun, Y.D. Wang, L. Zuo, R.D.K. Misra, Improved ductility of a transformation-induced-plasticity steel by nanoscale austenite lamellae, Mater. Sci. Eng. A, 583 (2013)1–10. [25] Y.F.Shen*, C.H. Qiu, L. Wang, X. Sun, X.M. Zhao, L. Zuo. Effects of cold rolling on microstructure and mechanical properties of Fe–30Mn–3Si–4Al–0.093C TWIP steel, Mater Sci Eng A, 561(2013)329-337. [26] X.M. Zhao, Y.F. Shen*, L.N. Qiu, X. Sun, L. Zuo. Effects of Intercritical Annealing Temperature on Mechanical Properties of Fe-7.9Mn-0.14Si-0.05Al-0.07C Steel, Materials, 7 (2014) 7891-7906. [27] Y.F. Shen, N. Jia*, Y.D. Wang, X. Sun, L. Zuo, D. Raabe. Suppression of twinning and phase transformation in an ultrafine grained 2 GPa strong metastable austenitic steel: Experiment and simulation, Acta Mater., 97 (2015) 305-315. [28] Y.F. Shen, R.G. Guan, Z.Y. Zhao, R.D.K. Misra. Ultrafine-grained Al–0.2Sc–0.1Zr alloy: The mechanistic contribution of nano-sized precipitates on grain refinement during the novel process of accumulative continuous extrusion, Acta Mater., 100 (2015) 247-255. [29] R.D.K. Misra, V.S.A. Challa, Y.F. Shen, M.C. Somani, L.P. Karjalainen. Interplay between grain structure, deformation mechanisms and austenite stability in phase-reversion-induced nanograined/ultrafine-grained austenitic ferrous alloy, Acta Mater. , 84 (2015) 339-348. [30] Y.F. Shen*, P.J. Wang, Y.D. Liu, R.D.K. Misra, L. Zuo. Activated dynamic strain aging of a TRIP590 steel at 300°C and low strain rate and relationship to structure, Mater. Sci. Eng. A, 645 (2015) 333-338. [31] Y.F. Shen*, L.N. Qiu, X. Sun, L. Zuo, P.K. Liaw, D. Raabe. Effects of retained austenite volume fraction, morphology, and carbon content on strength and ductility of nanostructured TRIP-assisted steels, Mater. Sci. Eng. A, 636 (2015) 551-564. [32] Y.F. Shen*, N. Jia, L. Zuo, R.D.K. Misra, Softening behavior by excessive twinning and adiabatic heating at high strain rate in a Fe-20Mn-0.6C TWIP steel, Acta Mater., 103 (2016) 229-242. [33] R.G. Guan, Y.F. Shen*, Z.Y. Zhao, R.D.K. Misra. Nanoscale precipitates strengthened lanthanum-bearing Mg-3Sn-1Mn alloys through continuous rheo-rolling, Scientific Reports, 6 (2016) 23154 . [34] R.G. Guan, Y.F. Shen*, Z.Y. Zhao, X. Wang. A high-strength, ductile Al-0.35Sc-0.2Zr alloy with good electrical conductivity strengthened by coherent nanosized-precipitates, J. Mater. Sci. Technol., 33 (2017) 215–223. [35] N. Jia, Y.F. Shen*, J.W. Liang, X.W. Feng, H.B. Wang, R.D.K. Misra. Nanoscale spheroidized cementite induced ultrahigh strength-ductility combination in innovatively processed ultrafine-grained low alloy medium-carbon steel, Scientific Reports, 7 (2017) 2679. [36] Y.X. Zhou, X.T. Song, J.W. Liang, Y.F. Shen*, R.D.K. Misra, Innovative processing of obtaining nanostructured bainite with high strength - high ductility combination in low-carbon-medium-Mn steel: Process-structure-property relationship, Mater. Sci. Eng. A, 718 (2018) 267-276. [37] J.W. Liang, Y.F. Shen*, C.S. Zhang, X.W. Feng, H.B. Wang, X. Sun, In situ neutron diffraction in quantifying deformation behaviors of nanosized carbide strengthened UFG ferritic steel, Mater. Sci. Eng. A, 726 (2018) 298-308. [38] X.W. Feng, J. Xie, W.Y. Xue, Y.F. Shen*, H.B. Wang, Z.Y. Liu, Microstructure and nanoindentation hardness of shot-peened ultrafine-grained low-alloy steel, J. Iron Steel Res. Int., 718 (2018) 267-276. [39] K. Li, B. Yu, R.D.K. Misra*, G. Han, S. Liu, Y.F. Shen, C.S. Shang, On the origin and contribution of extended kinks and jogs and stacking fault ribbons to deformation behavior in an ultrahigh strength cobalt-free maraging steel with high density of low lattice misfit precipitates, Mater. Sci. Eng. A, 728 (2018) 208-217. [40] Z.Y. Zhao*, R.G. Guan, Y.F. Shen, J. Li,K. P. Bai. Temperature distribution and its influence on microstructure of Mg–3Sn–1Mn alloy during rheo-rolling process,Phi. Mag., 98 (2018) 2367-2379. [41] J.W. Liang, X. Wang, X.L. Zhang, Y.F. Shen*, Development of low-alloy steels with high strength and good ductility with the aid of nanoscale troostite, J Mater. Eng. Perf., 28 (2019) 1639-1649. [42] W.Y. Xue, J.H. Zhou, Y.F. Shen*,W.N. Zhang, Z.Y. Liu, Micromechanical behavior of a fine-grained china low activation martensitic (CLAM) steel, J. Mater. Sci. Technol., 35 (2019) 1869-1876. [43] W.Y. Xue, Y.F. Shen*, J.H. Zhou, R.D.K. Misra, Z.Y. Liu, The significant impact of grain structure on large strain-rate sensitivity of ultrafine-grained low alloy steel under nanoscale deformation: Experimental and theoretical analysis, Mater. Sci. Eng. A, 755 (2019) 138-146. [44] Y.F. Shen*, X.X. Dong, X.T. Song, N. Jia, Carbon content-tuned martensite transformation in low-alloy TRIP steels, Scientific Reports, 9 (2019) 7559. [45] X.X. Dong, Y.F. Shen*, T.W. Yin,, R.D.K. Misra, G. Lin, Strengthening a medium-carbon steel to 2800 MPa by tailoring nanosized precipitates and the phase ratio, Mater. Sci. Eng. A, 759 (2019) 725-735. [46] Y. Chen, Y.J. Luo, Y.F. Shen∗, Y. Liu, R.D.K. Misra, Cumulative contribution of grain structure and twin boundaries on cyclic deformation behavior of a 20Mn-0.6C- TWIP steel: Experimental and theoretical analysis, Mater. Sci. Eng. A, 767 (2019) 138415. [47] X.X. An, Y. Tian*, H.J. Wang, Y.F. Shen, Z.D. Wang, Suppression of austenite grain coarsening by using Nb–Ti microalloying in high temperature carburizing of a gear steel, Adv. Eng. Mater., 21 (2019) 1900132. [48] J. Wang, Y.F. Shen∗, Y. Liu, F.G. Wang, N. Jia, Tailoring strength and ductility of a Cr-containing high carbon steel by cold-working and annealing, Materials, 12 (2019) 4136. [49] J.H. Zhou, Y.F. Shen∗, Y.Y. Hong, W.Y. Xue, R.D.K. Misra, Strengthening a fine-grained low activation martensitic steel by nanosized carbides, Mater. Sci. Eng. A, 769 (2020) 138471. [50] Z.F. He, N. Jia∗, H.W. Wang, Y. Liu, D.Y. Li, Y.F. Shen∗, The effect of strain rate on mechanical properties and microstructure of a metastable FeMnCoCr high entropy alloy, Mater. Sci. Eng. A, 776 (2020) 138982. [51] Y. Tian, J.H. Zhou, Y.F. Shen∗, Z.Z. Qu, W.Y. Xue, Z.D. Wang, Improved toughness of a high strength low alloy (HSLA) steel for Arctic Ship by Ni addition, Adv. Eng. Mater., 22 (2020) 1901553. [52] J.H. Zhou, Y.F. Shen∗, W.Y. Xue, N. Jia*, R.D.K. Misra, Improving strength and ductility of low activation martensitic (LAM) steel by alloying with titanium and tempering, Mater. Sci. Eng. A, 7769 (2021) 140152. [53] J.H. Zhou, Y.F. Shen∗, N. Jia*, Strengthening mechanisms of the reduced activated ferritic/martensitic steels: A review, Inter. J. Mine. Metall. Mater., 28 (2021) 335-348. [54] X.X. Dong, Y.F. Shen*,W.Y. Xue, N.Jia*, Improved work hardening of a medium carbon-TRIP steel by partial decomposition of retained austenite, Mater. Sci. Eng. A, 803 (2021) 140504. [55] J.Wang, Y.F. Shen*,W.Y. Xue, N. Jia*, R.D.K. Misra, The significant impact of introducing nanosize precipitates and decreased effective grain size on retention of high toughness of simulated heat affected zone (HAZ), Mater. Sci. Eng. A, 803 (2021) 140484. [56] J.W. Liang, Y.F. Shen*, R.D.K. Misra, P.K. Liaw, High strength-superplasticity combination of ultrafine-grained ferritic steel: the significant role of nanoscale carbides, J. Mater. Sci. Technol., 83 (2021) 131-144. [57] Z.F. He, H.L. Yan, Y.F. Shen, N. Jia*, M.W. Zhu, X.J. Guan, X.L. Zhao, S.B. Jin, G. Sha, Y.T. Zhu, C.T. Liu, Multi-heterostructure and mechanical properties of N-doped FeMnCoCr high entropy alloy, Inter. J. Plasticity, 139 (2021) 102965. [58] Z.F. He, N. Jia*, H.W. Wang, H.L. Yan, Y.F. Shen*, Synergy effect of multi-strengthening mechanisms in FeMnCoCrN HEA at cryogenic temperature, J. Mater. Sci. Technol., 86 (2021) 158-170. [59] Z.Y. Zhao, N. Guan*, Y.F. Shen*, P.K. Bai, Grain refinement mechanism of Mg-3Sn-1Mn-1La alloy during accumulative hot rolling, J. Mater. Sci. Technol., 91 (2021) 251-261. [60] X.X. Dong, S. Liu, Y.F. Shen*, N. Jia*, Isothermal holding treatment of a transformation-induced plasticity steel for obtaining ultrahigh strength and high plasticity, J Mater. Eng. Perf., 30 (2021) 4504-4517. [61] J.H. Zhou, Y.F. Shen*, W.Y. Xue, N. Jia*, Hot-deformation induced static recrystallization and nano-MX precipitation in a low activation martensitic steel, J Nucl. Mater., 556 (2021) 153190. [62] M.Y. He, Y.F. Shen*, N. Jia*, P.K. Liaw, C and N doping in high-entropy alloys: A pathway to achieve desired strength-ductility synergy, Applied Materials Today 25 (2021) 101162. [63] M.Y. He, N. Jia, X.C. Liu*, Y.F. Shen*, L. Zuo, Abnormal chemical composition fluctuations in multi-principal-element alloys induced by simple cyclic deformation, J. Mater. Sci. Technol., 113 (2022) 287–295. [64] W.Y. Xue, H.F. Zhang, Y.F. Shen*, N. Jia, Manganese controlled transformation and twinning of the nanoscale austenite in low-carbon-medium-Mn steel, Mater. Sci. Eng. A, 829 (2022) 142162 [65] X.X. Dong, Y.F. Shen*, N. Jia, Y.T. Zhu, Improving mechanical properties and retained-austenite stability of a medium carbon Q&P steel by adjusting phase ratio, Mater. Sci. Eng. A, 833 (2022) 142580 [66] J.W. Liang, Y.F. Shen*, Y.Z. Li, X.W. Feng, G.D. Wang, Nanosized precipitates activating ultrahigh strength of an ultrafine-grained ferritic steel during dynamic deformation, Mater. Sci. Eng. A, 841 (2022) 143040 [67] C. Sun, Y.F. Shen*, W.Y. Xue, Ultrahigh strength induced by superstorage capacity of dislocations in an ultrafine-grained Fe-9Mn-0.15Si-0.26C steel, J Mater. Eng. Perf., 31 (2022) 6773-6783 [68] Y.L. Wang, Y.F. Shen*, N. Jia, J.J. Wang, S.-X. Zhao, Acicular martensite induced superior strength-ductility combination in a 20Cr2Ni2MoV steel, Mater. Sci. Eng. A, 848 (2022) 143400 [69] G.Q. Li, Y.F. Shen*, N. Jia, X.W. Feng, W.Y. Xue, Microstructural evolution and mechanical properties of a micro-alloyed low-density δ-TRIP steel, Mater. Sci. Eng. A, 848 (2022) 143430 [70] T.W. Yin, Y.F. Shen*, W.Y. Xue, N. Jia, L. Zuo, Ce addition enabling superior strength and ductility combination of a low-carbon low-manganese transformation-induced plasticity steel, Mater. Sci. Eng. A, 849 (2022) 143474 [71] L.Y. Kan, T. Zhu, Q.B. Ye, Y.F. Shen, H.T. Wang, Q.H. Wang, T. Zhao, Z.D. Wang, Enhanced mechanical properties of a low-carbon martensitic steel by thermally stable Ni-rich austenite, Steel Resear. Inter., 93 (2022) 2100562 [72] Z.Z. Yang, X.W. Feng, X.L. Zhang, Y.F. Shen, X.C. Huang, R.Z. Xie, Study on dynamic mechanical behaviors and J–C constitutive model of a fine-grained D6A steel, Crystals, 12 (2022) 806 [73] X.X. Dong, Y.F. Shen*, Improving mechanical properties and corrosion resistance of 0.5 wt. % C TRIP steel by adjusting retained austenite stability and microstructural constituents, Mater. Sci. Eng. A, 852 (2022) 143737 [74] X.X. Dong, Y.F. Shen*, Y.T. Zhu, Moderating strain hardening rate to produce high ductility and high strength in a TRIP steel, Mater. Res. Lett., 11 (2023) 69–75 [75] L.Y. Kan, Q.B. Ye, Y.F. Shen*, Z.D. Wang, T. Zhao, Co-precipitation of nanosized Cu and carbides improving mechanical properties of 1 GPa grade HSLA steel, Mater. Sci. Eng. A, 859 (2022) 144211 [76] Z.F. He, Y.X. Guo, L.F. Sun, H.L. Yan, X.J. Guan, S. Jiang, Y.F. Shen*, W. Yin, X.L. Zhao, Z.M. Li, N. Jia*, Interstitial-driven local chemical order enables ultrastrong face-centered cubic multicomponent alloys, Acta Mater., 243(2023) 118495. [77] M.Y. He, Y.F. Shen*, N. Jia*, Peter K. Liaw, L. Zuo, Achieving sustainable strain hardening in a carbon-doped CuFeMnNi high-entropy alloy via dual-level heterogeneous microstructures, J. Alloy. Compd., 939 (2023) 168831. [78] Y.T. Wang, Y.F. Shen*, N. Jia, J.J. Wang, W.Y. Xue, Dynamic recrystallization and constitutive equation of 15Cr-10Mn-Ni-N steel under hot deformation, Mater. Today Commun., 3.5 (2023) 105648. [79] X.X. Dong, Y.F. Shen*, N. Jia, W.Y. Xue, Simultaneous enhancement of strength and ductility in a medium carbon low-alloy steel induced by secondary martensite and Cu-rich particles, Mater. Sci. Eng. A, 869 (2023) 144791. [80] Y.Z. Li, Y.F. Shen*, S.-X. Zhao*, W.N. Zhang, W.Y. Xue, Strengthening a medium-carbon low-alloy steel by nanosized grains: the role of asymmetrical rolling, Nanomaterials, 13 (2023) 956. [81] M.Y. He, Y.F. Shen*, N. Jia*, J.J. Wang, Microstructures and mechanical properties of a carbon-doped CuFeMnNi multiple-principal-element alloy, Mater. Charcter., 202 (2023) 112996. [82] T.W. Yin, Y.F. Shen*, N. Jia*, Y.J. Li, W.Y. Xue, Controllable selection of martensitic variant enables concurrent enhancement of strength and ductility in a low-carbon steel, Inter. J. Plasticity, 13 (2023) 956. [83] Y.X. Liu, H.F. Zhang, Y.L. Yang, L.F. Sun, X.L. Zhao, H.Y. Yan, Y.F. Shen*, N. Jia*, Chemical short-range order dependence of micromechanical behavior in CoCrNi medium-entropy alloy studied by atomic simulations, J. Alloy. Compd., 939 (2023) 172002. [84] M.Z. Wang, Y.F. Shen*, N. Jia, W.Y. Xue, Z.D. Wang, Ultrahigh strength triggered by BCC and B2 eutectic-phase interfaces in a novel FeCrVNiAl high-entropy alloy, Materials Research Letters, 2024, 12: 745 [85] T.J. Chen, E.X. Cui, Y.F. Shen*, Z.D. Wang, Z.J. Fan, Superior combination of strength and ductility in Fe–10Mn-0.6C steel trigged by austenite reversion transformation, Materials Science and Engineering: A, 2024, 901:146579 [86] J.J. Zhang, Y.F. Shen*, W.Y. Xue, Z.J. Fan, Enhancing strength and ductility of a Ni-26.6Co-18.4Cr-4.1Mo-2.3Al-0.3Ti-5.4Nb alloy via nanosized precipitations, stacking faults, and nanotwins, Nanomaterials, 2024, 14: 1296 [87] E.X. Cui, T.J. Chen, Y.F. Shen*, Z.D.Wang, Z.J. Fan, Superior combination of strength and ductility in Fe-20Mn-0.6C steel processed by asymmetrical rolling, Materials Today Communications, 2024, 40:110064 [88] W.N. Zhang, Z.J. Gao, H. Wei, H.M. Zhang, Z.J. Chen, W.Y. Xue,Y.F. Shen*, Z.Y. Liu, Investigation of the crystallographic evolution sequence of nano-precipitation via HRTEM in Cu-bearing ultra-low carbon steel, Nanomaterials, 2024, 14: 1335 [95] W,Y, Niu; X,L, Zhang; J,W, Liang; Y.F. Shen*; W,Y, Xue; J,P, Li; Role of nano-bainite laths and nanosized precipitates: Strengthening a low-alloy steel to 1870 MPa, Journal of Materials Research and Technology, 2024, 33: 2331-2342 [96] X,W, Feng; Z,Z, Yang; X,L, Zhang; Y.F. Shen*; Mechanical properties of fine-grained low alloy steel investigated by crystal plasticity finite element method, Journal of Materials Engineering and Performance, 2024, 21: 11627-11638 [97] L,F, Sun; Z,F, He; N, Jia*; Y,X, Guo; S, Jiang; Y,L, Yang; Y,X, Liu; X,J, Guan; Y.F. Shen*; H,L, Yan*; P,K, Liaw; Local chemical order enables an ultrastrong and ductile high-entropy alloy in a cryogenic environment, Science Advances, 2024, 10:eadq639 [98] C,W, He; Y,F, Shen*; W,Y, Xue, Z,J, Fan, Y, R, Zhou; Nanosized κ-Carbide and B2 boosting strength without sacrificing ductility in a low-density Fe-32Mn-11Al steel, Nanomaterials, 2025, 15: 48 [99] M,Z, Wang; Y,F, Shen*; W.Y. Xue; Achieving ultrahigh strength and good ductility in a Al5Co21Fe21Mn17Ni36 high-entropy alloy with BCC and FCC crystals, Intermetallics, 2025, 179: 108667 [100] B.W. Zhang; T.W. Yin; Y,F, Shen*; X. Sun; Simultaneous enhancement of impact strength and toughness of a low carbon steel with co-precipitation of nanoparticles, Materials Science and Engineering: A, 2025, 942:148683 [101] M.Z. Wang, Y.F. Shen*, N. Jia, W.Y. Xue, X.L. Wang; Multistage precipitation triggering 3 GPa compressive strength and superior corrosion resistance in a FeCrVNiAl alloy, Materials Futures, 4 (2025) 035004 [102] M,Z, Wang, M,Y, He, Y.F. Shen*, W.Y. Xue, Z,J, Fan; [103] H,N, Guo; M,Z, Wang; Y.F. Shen*,W.Y. Xue; Enhancing the plasticity and strength of Co19Cr19Fe19Ni30Nb13 eutectic high entropy alloy by γ′′ phase, J. Alloy. Compd., 1039 (2025) 183006 [104] J,J, Zhang; Y.F. Shen*;N, Jia*; W.Y. Xue; Z,D, Wang; Multiscale heterostructure and grain rotation promote the coordinated deformation of a multi-principal element alloy, J. Mater. Sci. Technol., 113 (2022) 287–295 |