王倩倩

姓名：王倩倩

性别：女

党派：中共党员

职称：副教授、博导

联系方式：qwang678@seu.edu.cn

研究方向:

1、超高温难熔高熵合金力学及热防护性能研究

2、非晶合金/高熵合金化学性能（耐腐蚀、降解、催化）研究

3、超高温陶瓷薄膜微结构调控与力学、多频谱兼容伪装、光热转换性能研究

个人网页：/mmlab/

王倩倩，永乐高60net副教授、博导，从事非晶高熵合金研究，主持国家自然科学基金面上、青年基金项目，江苏省基础研究计划（自然科学基金）面上项目。参与国家重点研发计划项目课题、国家自然科学基金重点项目、军委科技委基础加强计划重点基础研究项目课题、国家部委项目课题、江苏省成果转化专项资金项目等国家级、省部级科研项目多项。发表SCI论文50余篇，其中在Nature Communications、Small、Advanced Functional Materials、Journal of Materials Chemistry A、Nano Research（ESI高被引）等期刊以第一/通讯作者发表论文20余篇，被引1700余次。申请发明专利36件，其中15件已获授权，编写团体标准1项。入选2025年度全球前2%顶尖科学家榜单。获2022年度江苏省科学技术二等奖（5/9）。

教育经历

2008.09-2012.09

美国加州大学河滨分校（University of California, Riverside），化学与环境工程系，博士

2004.09-2008.06

华中科技大学，永乐高60net，学士

工作经历

2022.12 -至今       东南大学，永乐高60net，材料加工支部书记

2020.09-2025.11  东南大学，永乐高60net，材料加工工程系主任

2020.04 -至今        东南大学，永乐高60net，副教授

2014.02-2020.04  东南大学，永乐高60net，讲师

荣誉和奖励

2022年度江苏省科学技术二等奖（5/9）

2015年度江苏省“双创博士”

主要主持项目

1. 国家自然科学基金面上项目，核电乏燃料贮存用高熵非晶涂层高通量设计及使役损伤行为研究，2026/01-2029/12

2.国家自然科学基金青年科学基金项目，钴基磁敏非晶合金非晶形成能力和塑性变形能力研究，2016/01-2018/12

3.江苏省基础研究计划（自然科学基金）面上项目，铁基非晶合金高效降解染料性能及机理研究，2019/07-2022/06

4.东南大学基本科研业务费-国防基金重点项目，超高温高熵合金陶瓷复合材料设计与制备，2019/01-2020/12

5. 中央高校基本科研业务费-基础科研扶持项目，铁基非晶合金在染料废水处理中的应用探索及机理研究，2018/01-2018/12

主要参与项目

1. 国家重点研发计划项目“面向第三代半导体应用的高频软磁材料”课题二，2022/11-2025/10

2.国家自然科学基金重点项目，铁磁性无序合金结构调控及功能特性研究，2023/01-2027/12

3. 国家部委基础加强计划重点基础研究项目“超高温材料成形技术基础”课题一，超高温材料高通量设计与制备，2019/12-2024/12

4.国家自然科学基金重点项目，高性能铁磁性块体非晶合金的探索与结构性能研究，2017/01-2021/12

5. 国家部委前沿科技创新项目，增材制造先进非晶合金武器装备，2017/07-2018/06

论文发表

[1] B. Sun, B.J. Wang, Z. Jia, L.G. Sun, J. Kuang, Qianqian Wang*, G. Sha, X.B. Liang*, B.L. Shen*, Strength-plasticity synergy from ambient to high temperature via gradient-ordering in boride-reinforced WTaV medium-entropy alloy, Nature Communications, https://doi.org/10.1038/s41467-025-66617-8.

[2] F.K. Xiong, G.P. Zou, Y.X. Q, B. Sun, B.S. Zhang, S.S. Zhu, T. Liang, Q.S. Zeng, X.H. Zhang, Qianqian Wang*, B.L. Shen*, Data-driven high-throughput screening of Fe-Cr-Mo-C-B amorphous alloy with excellent corrosion and wear resistance, Corrosion Science, 258 (2026) 113450.

[3] G.P. Zou, Qianqian Wang*, R.X. Sheng, L.G. Sun, Q.Y. Shao, X.H. Zhang, Z. Jia, B.L. Shen*，Wear-resistant HfCx film with infrared-visible compatible stealth property，Ceramics International, 51 (2025) 28382-28393.

[4] Z.J. Guo, Y.Z. Ye, Z.J. Zhou, Qianqian Wang*, B.S. Zhang*, B.L. Shen*, Novel FeNiCrMoCBPNb High-Entropy Amorphous Coatings Prepared by Atmospheric Plasma Spraying with Excellent Corrosion and Wear Properties, Journal of Thermal Spray Technology, 34 (2025) 394-408.

[5] J. Kuang, Qianqian Wang, Z. Jia*, G.M. Yi, B. Sun, Y.Y. Yang, L.G. Sun, P. Zhang, P.F. He, Y. Xing, X.B. Liang*, Y. Lu*, B.L. Shen*, Ablation-resistant yttrium-modified high-entropy refractory metal silicide (NbMoTaW)Si2 coating for oxidizing environments up to 2100 °C, Materials Today, 80 (2024) 156-166.

[6] Y.Z. Ye, Z.J. Guo, Z.J. Zhou, B.S. Zhang, QianqianWang*, B.L. Shen*，Improved corrosion and corrosion-wear properties of Fe-based high-entropy amorphous coatings by modulating heat input of HVAF,Corrosion Science, 232 (2024) 112049.

[7] B. Sun, Qianqian Wang*, J.Y. Mo, B.J. Wang, X.B. Liang*, B.L. Shen*, Promoted high-temperature strength and room-temperature plasticity synergy by tuning dendrite segregation in NbMoTaW refractory high-entropy alloy, International Journal of Refractory Metals & Hard Materials, 118 (2024) 106469.

[8] B. Sun, J.Y. Mo, Qianqian Wang, Y.X. Chen, Z.B. Zhang, B.L. Shen*, L.B. Liang*, Outstanding specific yield strength of a refractory high-entropy composite at an ultrahigh temperature of 2273 K, Journal of Materials Science and Technology, 166 (2023) 145-154.

[9] B.J. Wang, Qianqian Wang, B. Sun, J.Y. Mo, Y.B. Guo, X.B. Liang*, B.L. Shen*, Nitride-reinforced HfNbTaTiV high-entropy alloy with excellent room and elevated-temperature mechanical properties, Journal of Materials Science and Technology,149 (2023) 31-41.

[10] B. Sun, Qianqian Wang*, Y.X. Chen, B.J. Wang, M. Xia, T. Gu, S.S. Zhu, B.S. Zhang, X.B. Liang*, B.L. Shen*, Design of heterogeneous structure for enhancing formation quality of laser-manufactured WTaMoNb refractory high-entropy alloy, Journal of Alloys and Compounds, 953 (2023) 170066.

[11] S.Y. Di, J. Zhou, M.J. Cai, J.X. Cui, X.S. Li, B.L. Shen, H.B. Ke*, Qianqian Wang*, Improved ductility of annealed Fe-based metallic glass with good soft magnetic property by cryogenic thermal cycling, Journal of Alloys and Compounds, 960 (2023) 170686.

[12] Qianqian Wang, Z. Jia, J.Q. Li, Y.Z. He, Y.Y. Yang, L.G. Sun, B.L. Shen*, Attractive Electron Delocalization Behavior of FeCoMoPB Amorphous Nanoplates for Highly Efficient Alkaline Water Oxidation, Small, 18 (2022) 2204135.

[13] Qianqian Wang, J.Q. Li, Y.J. Li, G.M. Shao, Z. Jia, B.L. Shen*, Non-noble metal-based amorphous high-entropy oxides as efficient and reliable electrocatalysts for oxygen evolution reaction, Nano Research, 15 (2022) 8751-8759. （ESI高被引）

[14] B. Sun, Qianqian Wang, Y.X. Chen, J.B. Cheng, H.C. Zhao, S.S. Zhu, B.S. Zhang, X.B. Liang*, B.L. Shen*, Dendrite refinement and wear performance enhancement in laser-cladded Fe-based coatings after multi-step laser remelting, Surface & Coatings Technology, 447 (2022) 128794.

[15] S. Y. Di, H.B. Ke, Qianqian Wang, J. Zhou, Y. Zhao, B.L. Shen*, Large tensile plasticity induced by pronounced β-relaxation in Fe-based metallic glass via cryogenic thermal cycling, Materials & Design, 222 (2022) 111074.

[16] B.J. Wang, Q.Q. Wang, N. Lu, X.B. Liang, B.L Shen, Enhanced high-temperature strength of HfNbTaTiZrV refractory high-entropy alloy via Al2O3 reinforcement, J. Mater. Sci. Technol. 123 (2022) 191-200.

[17] J. Kuang, P. Zhang, Q.Q. Wang, Z.F. Hu, X.B. Liang*, B.L. Shen*, Formation and oxidation behavior of refractory high-entropy silicide (NbMoTaW)Si₂ coating, Corrosion Science, 198 (2022) 110134.

[18] S.Y. Di, Qianqian Wang, Y.Y. Yang, T. Liang, J. Zhou, L. Su, K.B. Yin, Q.S. Zeng, L.T. Sun, B.L. Shen*, Efficient rejuvenation of heterogeneous {[(Fe_0.5Co_0.5)_0.75B_0.2Si_0.05]₉₆Nb₄}_99.9Cu_0.1 bulk metallic glass upon cryogenic cycling treatment, Journal of Materials Science and Technology, 2022, 97: 20-28.

[19] F. Miao^#, Qianqian Wang^#, L.C. Zhang*, B.L. Shen*, Magnetically separable Z-scheme FeSiB metallic glass/g-C3N4 heterojunction photocatalyst with high degradation efficiency at universal pH conditions, Applied Surface Science, 2021, 540: 148401.

[20] G.M. Shao, Qianqian Wang, F. Miao, J.Q. Li, Y.J. Li, B.L. Shen*, Improved catalytic efficiency and stability by surface activation in Fe-based amorphous alloys for hydrogen evolution reaction in acidic electrolyte, Electrochimica Acta, 2021, 390: 138815.

[21] Qianqian Wang, X.D. Bai, B. Sun, J. Liu, Z.H. Cai, X.B. Liang, B.L. Shen*, Influence of Si on tribological behavior of laser cladded Fe-based amorphous/crystalline composite coating, Surface and Coatings Technology, 2021, 405: 126570.

[22] Qianqian Wang, X. Yang, Z.Q. Cui, L. Xue, L.L. Shao, Q. Luo, B.L. Shen*, Effects of C/B ratio on glass-forming ability and low-temperature magnetic behavior of FeCoCrMoCBTm metallic glass, Journal of Alloys and Compounds, 2021, 864: 158211.

[23] J. Zhou, Qianqian Wang, Q.S. Zeng, K.B. Yin, A.D. Wang, J.H. Luan, L.T. Sun, B.L. Shen*, A plastic FeNi-based bulk metallic glass and its deformation behavior, Journal of Materials Science and Technology, 2021, 76: 20-32.

[24] F. Miao, Qianqian Wang*, S.Y. Di, L. Yun, J. Zhou, B.L. Shen, Enhanced dye degradation capability and reusability of Fe-based amorphous ribbons by surface activation, Journal of Materials Science and Technology, 53 (2020) 163-173.

[25] F. Miao, Qianqian Wang*, Q.S. Zeng, L. Hou, T. Liang, Z.Q. Cui, B.L. Shen, Excellent reusability of FeBC amorphous ribbons induced by progressive formation of through-pore structure during acid orange 7 degradation, Journal of Materials Science and Technology, 38 (2020) 107-118.

[26] S.Y. Di, Qianqian Wang, J. Zhou, Y.Y. Shen, J.Q. Li, M.Y. Zhu, K.B. Yin, Q.S. Zeng, L.T. Sun, B.L. Shen*, Enhancement of plasticity for FeCoBSiNb bulk metallic glass with superhigh strength through cryogenic thermal cycling, Scripta Materialia, 2020, 187: 13-18.

[27] J. Zhou, Qianqian Wang, X.D. Hui, Q.S. Zeng, Y.W. Xiong, K.B. Yin, B.A. Sun, LT. Sun, M. Stoica, W.H. Wang, B.L. Shen*, A novel FeNi-based bulk metallic glass with high notch toughness over 70 MPa m^1/2 combined with excellent soft magnetic properties, Materials & Design, 2020, 191:108597.

[28] Qianqian Wang, J. Zhou, Q.S. Zeng, G.L. Zhang, K.B. Yin, T. Liang, W.M. Yang, M. Stoica, L.T. Sun, B.L. Shen*, Ductile Co-based bulk metallic glass with superhigh strength and excellent soft magnetic properties induced by modulation of structural heterogeneity, Materialia, 2020, 9: 100561.

[29] Qianqian Wang, G.L. Zhang, J. Zhou, C.C. Yuan, B.L. Shen*, Effects of Ni substitution for Fe/Co on mechanical and magnetic properties of Co-based bulk metallic glasses, Journal of Alloys and Compounds, 2020, 820: 153105.

[30] Qianqian Wang, L. Yun, M.X. Chen, D.D. Xu, Z.Q. Cui, Q.S. Zeng, P.H. Lin, C.L. Chu, B.L. Shen*, Competitive effects of structural heterogeneity and surface chemical states on catalytic efficiency of FeSiBPCu amorphous and nanocrystalline alloys, ACS Applied Nano Materials, 2019, 2: 214-227.

[31] Qianqian Wang, M.X. Chen, L.L. Shao, Y.W. Ge, P.H. Lin, C.L. Chu*, B.L. Shen*, Effects of structural relaxation on the dye degradation ability of FePC amorphous alloys, Journal of Non-crystalline Solids, 2019, 525: 119671.

[32] W.M. Yang^#, Qianqian Wang^#, W.Y. Li, L. Xue, H.S. Liu*, J. Zhou, J.Y. Mo, B.L. Shen*, A novel thermal-tuning Fe-based amorphous alloy for automatically recycled methylene blue degradation, Materials and Design, 2019, 161: 136-146.

[33] W.M. Yang^#, Qianqian Wang^#, H.B. Ling, H.S. Liu*, L. Xue, Y.Z. He, Q. Li, B.L. Shen*, Oxygen-driven impurities scavenging before solidification of Fe-based metallic glasses, Journal of Alloys and Compounds, 2019, 773: 401-412.

[34] L. Hou, Qianqian Wang, X.D. Fan, F. Miao, W.M. Yang, B.L. Shen*, Effect of Co addition on catalytic activity of FePCCu amorphous alloy for methylene blue degradation, New Journal of Chemistry, 2019, 43: 6126-6135. (front cover)

[35] L. Hou^#, X.D. Fan^#, Qianqian Wang, W.M. Yang, B.L. Shen*, Microstructure and soft-magnetic properties of FeCoPCCu nanocrystalline alloys, Journal of Materials Science & Technology, 2019, 35: 1655-1661.

[36] J. Zhou, B.A. Sun, Qianqian Wang, Q.M. Yang, W.M. Yang, B.L. Shen*, Effects of Ni and Si additions on mechanical properties and serrated flow behavior in FeMoPCB bulk metallic glasses, Journal of Alloys and Compounds, 2019, 783: 555-564.

[37] L.L. Shao, L. Xue, Q. Luo, Qianqian Wang, B.L. Shen*, The role of Co/Al ratio in glass-forming GdCoAl magnetocaloric metallic glasses, Materialia, 2019, 7: 100419.

[38] Qianqian Wang, M.X. Chen, P.H. Lin, Z.Q. Cui, C.L. Chu*, B.L. Shen*, Investigation of FePC amorphous alloys with self-renewing behaviour for highly efficient decolorization of methylene blue, Journal of Materials Chemistry A, 6 (2018) 10686-10699.

[39] D.D. Xu^#, B.L. Zhou^#, QianQian Wang, J. Zhou, W.M. Yang, C.C. Yuan, L. Xue, X.D. Fan, L.Q. Ma, B.L. Shen*, Effects of Cr addition on thermal stability, soft magnetic properties and corrosion resistance of FeSiB amorphous alloys, Corrosion Science, 2018, 138: 20-27.

[40] L. Hou, Qianqian Wang, W.M. Yang, B.L. Shen*, Enhanced plasticity of FeCoBSiNb bulk glassy alloys by controlling the structure heterogeneity with Cu addition, Journal of Non-Crystalline Solids, 2018, 505: 181-187.

[41] G.L. Zhang, Qianqian Wang, C.C. Yuan, W.M. Yang, J. Zhou, L. Xue, F. Hu, B.A. Sun, B.L. Shen*, Effects of Cu additions on mechanical and soft-magnetic properties of CoFeBSiNb bulk metallic glasses, Journal of Alloys and Compounds, 2017, 737: 815-820.

[42] X.D. Fan, F.L. Zhu, Qianqian Wang, M.F. Jiang, B.L. Shen*, Effect of Magnetic Field Annealing on Microstructure and Magnetic Properties of FeCuNbSiB Nanocrystalline Magnetic Core with High Inductance, Applied Microscopy, 2017, 47(1): 29-35.

[43] W.M. Yang, C. Wan, H.S. Liu*, Q. Li, Qianqian Wang, H. Li, J. Zhou, L. Xue, B.L. Shen*, A. Inoue, Fluxing induced boron alloying in Fe-based bulk metallic glasses, Materials & Design, 2017, 129: 63-68.

[44] W.M. Yang, H.S. Liu*, Qianqian Wang, Z.N. Wei, L. Xue, C.C. Dun, Y.C. Zhao, C.T. Chang, B.L. Shen, Electronic structure of Cu_100-xZr_x (x=40, 50, 60) metallic glasses, Materials & Design, 2015, 82: 126-129.

[45] L.K. Grunenfelder, E.E. Obaldia, Qianqian Wang, D.S. Li, B. Weden, C. Salinas, R. Wuhrer, P. Zavattieri, D. Kisailus*,  Stress and Damage Mitigation from Oriented Nanostructures within the Radular Teeth of Cryptochiton stelleri, Advanced Functional Materials, 2014, 24: 6093–6104.

[46] Qianqian Wang, M. Nemoto, D.L. Li, J. C. Weaver, B. Weden, J. Stegemeier, K. N. Bozhilov, L. R. Wood, G. W. Milliron, C. S. Kim, E. DiMasi, D. Kisailus*, Phase transformations and structural developments in the radular teeth of cryptochiton stelleri, Advanced Functional Materials, 23 (2013) 2908-2917.

[47] M. Nemoto, Qianqian Wang, D.S. Li, S.Q. Pan, T. Matsunaga, D. Kisailus, Proteomic analysis from the mineralized radular teeth of the giant Pacific chiton, Cryptochiton stelleri (Mollusca), Proteomics, 2012, 12: 2890-2894.

[48] J. C. Weaver, Qianqian Wang, A. Miserez, A. Tantuccio, R. Stromberg, K. N. Bozhilov, P. Maxwell, R. Nay, S. T. Heier, E. DiMasi, D. Kisailus*, Analysis of an ultra hard magnetic biomineralsin chiton radular teeth, Materials Today, 2010, 13: 42-52.