基本情况

代表性论文：

[1] Y. Lu, R. Kotoka, J.P. Ligda, et al., The microstructure and mechanical behavior of multilayered Mg/Ti nanofilms as a function of layer thickness, Acta Materialia 63 (2014) 216-231.

[2] Y. Lu, M. Watanabe, R. Miyata, et al., Microstructures and mechanical properties of TiC-particulate-reinforced Ti–Mo–Al intermetallic matrix composites, Materials Science and Engineering A 790 (2020) 139523.

[3] Y. Lu, J. Yamada, R. Miyata, et al., High-temperature mechanical behavior of B2-structured Ti–Mo–Al alloys, Intermetallics 117 (2020) 106675.

[4] Y. Lu, N. Sekido, K. Yoshimi, et al., Microstructures and mechanical properties of Mg/Zr nanostructured multilayers with coherent interface, Thin Solid Films 712 (2020) 138314

[5] Y. Lu, J. Yamada, J. Nakamura, et al., Effect of B2-ordered phase on the deformation behavior of Ti-Mo-Al alloys at elevated temperature, Journal of Alloys and Compounds 698 (2017) 130-135.

[6] Y. Lu, R. Kotoka, J.P. Ligda, et al., Morphological and mechanical stability of HCP-based multilayer nanofilms at elevated temperatures, Surface and Coatings Technology 275 (2015) 142-147..

[7] Y. Lu, J. Zhang, L.X. Tian, et al., Microstructural evolution of unidirectionally solidified Nb_SS-Nb₅Si₃ eutectic Alloy, Rare Metals 30 Suppl. 1 (2011) 335.

[8] S.Y. Kamata, D. Kanekon, Y. Lu, et al., Ultra-high temperature tensile creep of MoSiTiC alloy, Scientific Report 8 (2018) 10487.

[9] X. Nan, M. Zhao, Y. Lu, et al., High-temperature oxidation behavior of a Ti₅Si₃-incorporated MoSiBTiC alloy, Intermetallics 125 (2020) 106895.

主讲课程

研究生课程：《先进结构材料力学性能测试与分析方法》

本科生课程：《金属凝固原理与工艺》、《科研课堂》

研究方向

（1）高温结构材料（钛铝合金、钼基合金等）

（2）高性能铝合金

（3）金属材料的力学性能及变形机理

教学科研成果

代表性论文：

[1] Y. Lu, R. Kotoka, J.P. Ligda, et al., The microstructure and mechanical behavior of multilayered Mg/Ti nanofilms as a function of layer thickness, Acta Materialia 63 (2014) 216-231.

[2] Y. Lu, M. Watanabe, R. Miyata, et al., Microstructures and mechanical properties of TiC-particulate-reinforced Ti–Mo–Al intermetallic matrix composites, Materials Science and Engineering A 790 (2020) 139523.

[3] Y. Lu, J. Yamada, R. Miyata, et al., High-temperature mechanical behavior of B2-structured Ti–Mo–Al alloys, Intermetallics 117 (2020) 106675.

[4] Y. Lu, N. Sekido, K. Yoshimi, et al., Microstructures and mechanical properties of Mg/Zr nanostructured multilayers with coherent interface, Thin Solid Films 712 (2020) 138314

[5] Y. Lu, J. Yamada, J. Nakamura, et al., Effect of B2-ordered phase on the deformation behavior of Ti-Mo-Al alloys at elevated temperature, Journal of Alloys and Compounds 698 (2017) 130-135.

[6] Y. Lu, R. Kotoka, J.P. Ligda, et al., Morphological and mechanical stability of HCP-based multilayer nanofilms at elevated temperatures, Surface and Coatings Technology 275 (2015) 142-147..

[7] Y. Lu, J. Zhang, L.X. Tian, et al., Microstructural evolution of unidirectionally solidified Nb_SS-Nb₅Si₃ eutectic Alloy, Rare Metals 30 Suppl. 1 (2011) 335.

[8] S.Y. Kamata, D. Kanekon, Y. Lu, et al., Ultra-high temperature tensile creep of MoSiTiC alloy, Scientific Report 8 (2018) 10487.

[9] X. Nan, M. Zhao, Y. Lu, et al., High-temperature oxidation behavior of a Ti₅Si₃-incorporated MoSiBTiC alloy, Intermetallics 125 (2020) 106895.