武曉燕
副研究員,碩士生導師
電子郵件: wuxiaoyan@ustb.edu.cn
科研方向
(1)金屬材料開發及組織性能控制;
(2)金屬材料攪拌摩擦焊;
(3)材料加工多尺度數值仿真模擬;
(2)金屬材料攪拌摩擦焊;
(3)材料加工多尺度數值仿真模擬;
簡歷
武曉燕,工學博士,副研究員、碩士生導師,2019年博士畢業于北京航空航天大學。聚焦航空、交通和能源等領域重大共性關鍵技術開展理論、方法與應用研究,在金屬材料設計、強韌化機理、熔鑄工藝及軋制工藝優化、數值仿真模擬等開展了大量研究工作。主持國家自然基金項目1項、中央高校基本科研業務費項目1項,負責/參與產學研合作橫向課題多項。以第一作者在MSEA、JAC等國際期刊發表論文20篇,申請國家發明專利10項,已授權發明專利3項,軟件著作權1項,榮獲中國有色金屬工業科學技術獎一等獎。
代表性著作
(1) Xiaoyan Wu, Haitao Jiang, Ruijie Zhao, et al. Microstructure Evolution of 7055-T76 Aluminum Alloy in the Coupled Thermal-Mechanical Severe Plastic Deformation Process of Friction Stir Welding: Grains, Texture, and Precipitates, Journal of Materials Engineering and Performance, 2025, 34(7): 5856-5867.
(2)武曉燕,藺宏濤,王怡嵩,等. 攪拌摩擦熱力耦合條件下 Q&P980 鋼焊核區組織演變規律,焊接學報,2023,44(6):120-128.
(3) Xiaoyan Wu, Hongtao Lin, Yisong Wang, et al. Hydrogen embrittlement and fracture mechanism of friction stir welded quenching and partitioning 980 steel, Materials Science & Engineering A, 2021, 802: 140683.
(4) Xiaoyan Wu, Hongtao Lin, Wei Luo, et al. Microstructure and microhardness evoluti on of thermal simulated HAZ of Q&P980 steel, Journal of Materials Research and Technology, 2021, 15: 6067-6078.
(5) Wu Xiaoyan, Luo Wei, Jiang Haitao. Effect of Probe length on microstructure and mechanical properties of Friction Stir lap-welded aluminum alloy and steel. Rare Metal Materials and Engineering, 2022, 51(09): 3197-3203.
(6) Xiaoyan Wu; Wei Luo; Huarui Zhang; et al. Effect of La addition on microstructure and mechanical properties of hypoeutectic Al-7Si aluminum alloy, China Foundry, 2021, 18(5): 481-487.(2)武曉燕,藺宏濤,王怡嵩,等. 攪拌摩擦熱力耦合條件下 Q&P980 鋼焊核區組織演變規律,焊接學報,2023,44(6):120-128.
(3) Xiaoyan Wu, Hongtao Lin, Yisong Wang, et al. Hydrogen embrittlement and fracture mechanism of friction stir welded quenching and partitioning 980 steel, Materials Science & Engineering A, 2021, 802: 140683.
(4) Xiaoyan Wu, Hongtao Lin, Wei Luo, et al. Microstructure and microhardness evoluti on of thermal simulated HAZ of Q&P980 steel, Journal of Materials Research and Technology, 2021, 15: 6067-6078.
(5) Wu Xiaoyan, Luo Wei, Jiang Haitao. Effect of Probe length on microstructure and mechanical properties of Friction Stir lap-welded aluminum alloy and steel. Rare Metal Materials and Engineering, 2022, 51(09): 3197-3203.
(6) Xiaoyan Wu; Wei Luo; Huarui Zhang; et al. Effect of La addition on microstructure and mechanical properties of hypoeutectic Al-7Si aluminum alloy, China Foundry, 2021, 18(5): 481-487.
(7) Xiaoyan Wu; Huarui Zhang; Haitao Jiang; et al. Multi-Refinement Effect of Rare Earth Lanthanum onα-Al and Eutectic Si Phase in Hypoeutectic Al-7Si Alloy, metals, 2020,10:621.
(8) Wu Xiaoyan, Zhang Huarui, Zhang Hu, et al. Quantitative Relationship Analysis Between Mechanical Properties and Microstructures of Al-7Si Aluminum Alloys by Artificial Neural Network, Rare Metal Materials and Engineering, 2021, 50(07): 2329-2336.
(9) Xiaoyan Wu, Huarui Zhang, Zhen Ma, et al. Interactions between Fe-rich intermetallics and Mg-Si phase in Al-7Si-xMg alloys, Journal of Allo ys and Compounds, 2019, 786: 205-214.
(10) Xiaoyan Wu, Huarui Zhang, Fengxiang Zhang, et al. Effect of cooling rate and Co content on the formation of Fe-rich intermetallics in hypoe utectic Al7Si0.3Mg alloy with 0.5%Fe, Materials Characterization, 2018, 139: 116-124.
(11) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Effect of holding pressure on microstructure and fracture behavior of low-pressure die cast A356-T6 alloy, Materials Research Express, 2017:1-8.
(12) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Evolution of microstructure and mechanical properties of A356 aluminium alloy processed by hot spinning process, China Foundry, 2017(14):138-144.
(13) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Effect of Holding Pressure on Microstructure and Mechanical Properties of A356 Aluminum Alloy, Journal of Materials Engineering and Performance, 2018(27):483-491.
(14) Wu Xiaoyan, Zhang Huarui, Ma Zhen, et al. Quantitative relationship analysis of mechanical properties with Mg content and heat treatment parameters in Al-7Si alloys using artificial neural network[J]. Materials, 2019 (12):718.
(15) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Microstructure and grain refinement performance of a new Al-5Nb-RE-B master alloy, Rare Metal Materials and Engineering, 2018 (47):2017-2022.
(2)武曉燕,藺宏濤,王怡嵩,等. 攪拌摩擦熱力耦合條件下 Q&P980 鋼焊核區組織演變規律,焊接學報,2023,44(6):120-128.
(3) Xiaoyan Wu, Hongtao Lin, Yisong Wang, et al. Hydrogen embrittlement and fracture mechanism of friction stir welded quenching and partitioning 980 steel, Materials Science & Engineering A, 2021, 802: 140683.
(4) Xiaoyan Wu, Hongtao Lin, Wei Luo, et al. Microstructure and microhardness evoluti on of thermal simulated HAZ of Q&P980 steel, Journal of Materials Research and Technology, 2021, 15: 6067-6078.
(5) Wu Xiaoyan, Luo Wei, Jiang Haitao. Effect of Probe length on microstructure and mechanical properties of Friction Stir lap-welded aluminum alloy and steel. Rare Metal Materials and Engineering, 2022, 51(09): 3197-3203.
(6) Xiaoyan Wu; Wei Luo; Huarui Zhang; et al. Effect of La addition on microstructure and mechanical properties of hypoeutectic Al-7Si aluminum alloy, China Foundry, 2021, 18(5): 481-487.(2)武曉燕,藺宏濤,王怡嵩,等. 攪拌摩擦熱力耦合條件下 Q&P980 鋼焊核區組織演變規律,焊接學報,2023,44(6):120-128.
(3) Xiaoyan Wu, Hongtao Lin, Yisong Wang, et al. Hydrogen embrittlement and fracture mechanism of friction stir welded quenching and partitioning 980 steel, Materials Science & Engineering A, 2021, 802: 140683.
(4) Xiaoyan Wu, Hongtao Lin, Wei Luo, et al. Microstructure and microhardness evoluti on of thermal simulated HAZ of Q&P980 steel, Journal of Materials Research and Technology, 2021, 15: 6067-6078.
(5) Wu Xiaoyan, Luo Wei, Jiang Haitao. Effect of Probe length on microstructure and mechanical properties of Friction Stir lap-welded aluminum alloy and steel. Rare Metal Materials and Engineering, 2022, 51(09): 3197-3203.
(6) Xiaoyan Wu; Wei Luo; Huarui Zhang; et al. Effect of La addition on microstructure and mechanical properties of hypoeutectic Al-7Si aluminum alloy, China Foundry, 2021, 18(5): 481-487.
(7) Xiaoyan Wu; Huarui Zhang; Haitao Jiang; et al. Multi-Refinement Effect of Rare Earth Lanthanum onα-Al and Eutectic Si Phase in Hypoeutectic Al-7Si Alloy, metals, 2020,10:621.
(8) Wu Xiaoyan, Zhang Huarui, Zhang Hu, et al. Quantitative Relationship Analysis Between Mechanical Properties and Microstructures of Al-7Si Aluminum Alloys by Artificial Neural Network, Rare Metal Materials and Engineering, 2021, 50(07): 2329-2336.
(9) Xiaoyan Wu, Huarui Zhang, Zhen Ma, et al. Interactions between Fe-rich intermetallics and Mg-Si phase in Al-7Si-xMg alloys, Journal of Allo ys and Compounds, 2019, 786: 205-214.
(10) Xiaoyan Wu, Huarui Zhang, Fengxiang Zhang, et al. Effect of cooling rate and Co content on the formation of Fe-rich intermetallics in hypoe utectic Al7Si0.3Mg alloy with 0.5%Fe, Materials Characterization, 2018, 139: 116-124.
(11) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Effect of holding pressure on microstructure and fracture behavior of low-pressure die cast A356-T6 alloy, Materials Research Express, 2017:1-8.
(12) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Evolution of microstructure and mechanical properties of A356 aluminium alloy processed by hot spinning process, China Foundry, 2017(14):138-144.
(13) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Effect of Holding Pressure on Microstructure and Mechanical Properties of A356 Aluminum Alloy, Journal of Materials Engineering and Performance, 2018(27):483-491.
(14) Wu Xiaoyan, Zhang Huarui, Ma Zhen, et al. Quantitative relationship analysis of mechanical properties with Mg content and heat treatment parameters in Al-7Si alloys using artificial neural network[J]. Materials, 2019 (12):718.
(15) Xiaoyan Wu, Huarui Zhang, Hu Zhang et al. Microstructure and grain refinement performance of a new Al-5Nb-RE-B master alloy, Rare Metal Materials and Engineering, 2018 (47):2017-2022.
獲獎
高精鋁板帶生產全流程質量智能管控技術及應用,中國有色金屬工業科學技術獎一等獎
專利
(1) 武曉燕; 江海濤; 曹志明; 等. 一種薄規格鈦鋼層狀復合板的攪拌摩擦焊方法, 2020-12-1, 中國, ZL201911174122.1
(2) 武曉燕; 江海濤; 吳彥欣; 等. 一種鈦鋼層狀復合薄卷制備方法, 2021-11-30, 中國, ZL202010463511.2
(3) 武曉燕; 江海濤; 吳彥欣; 等. 提高可熱處理強化鋁合金攪拌摩擦焊接接頭性能的方法, 2022-06-21, 中國, ZL202110514379.8
(4) 武曉燕,江海濤. 鋁合金力學性能預測軟件V1.0, 2024-03, 2024SR0383141(2) 武曉燕; 江海濤; 吳彥欣; 等. 一種鈦鋼層狀復合薄卷制備方法, 2021-11-30, 中國, ZL202010463511.2
(3) 武曉燕; 江海濤; 吳彥欣; 等. 提高可熱處理強化鋁合金攪拌摩擦焊接接頭性能的方法, 2022-06-21, 中國, ZL202110514379.8
(4) 武曉燕,江海濤. 鋁合金力學性能預測軟件V1.0, 2024-03, 2024SR0383141
(2) 武曉燕; 江海濤; 吳彥欣; 等. 一種鈦鋼層狀復合薄卷制備方法, 2021-11-30, 中國, ZL202010463511.2
(3) 武曉燕; 江海濤; 吳彥欣; 等. 提高可熱處理強化鋁合金攪拌摩擦焊接接頭性能的方法, 2022-06-21, 中國, ZL202110514379.8
(4) 武曉燕,江海濤. 鋁合金力學性能預測軟件V1.0, 2024-03, 2024SR0383141(2) 武曉燕; 江海濤; 吳彥欣; 等. 一種鈦鋼層狀復合薄卷制備方法, 2021-11-30, 中國, ZL202010463511.2
(3) 武曉燕; 江海濤; 吳彥欣; 等. 提高可熱處理強化鋁合金攪拌摩擦焊接接頭性能的方法, 2022-06-21, 中國, ZL202110514379.8
(4) 武曉燕,江海濤. 鋁合金力學性能預測軟件V1.0, 2024-03, 2024SR0383141
科研項目
(1)國家自然科學基金,攪拌摩擦非穩態熱力耦合劇塑變誘導7xxx系鋁合金動態析出行為及機理,負責
(2)橫向協作,1500熱軋板帶快冷技術的研究與應用,負責
(3)橫向協作,鋼質結構件焊接過渡區表面涂層測試與分析技術,負責
(4)橫向協作,提高可熱處理強化鋁合金攪拌摩擦焊接接頭性能的方法,負責
(2)橫向協作,1500熱軋板帶快冷技術的研究與應用,負責
(3)橫向協作,鋼質結構件焊接過渡區表面涂層測試與分析技術,負責
(4)橫向協作,提高可熱處理強化鋁合金攪拌摩擦焊接接頭性能的方法,負責