2024/7-至今 深圳大学 助理教授 2021/2-2024/7，松山湖材料实验室 博士后 2017/9-2021/1，中国科学院物理研究所 凝聚态物理 博士 2016/6-2017/7，中国科学院力学研究所 研究助理 2013/9-2016/6，中国科学院力学研究所 材料工程 硕士 2009/9-2013/6，山东大学 工程力学系 学士

邮箱: dongjie@szu.edu.cn 地址：深圳大学沧海校区致信楼S508

轻质、高强韧金属玻璃及其复合材料的高通量超声振动制造。 基于先进光源/中子源的材料原子结构解析，及其测试方法和仪器研发。 金属玻璃/非晶合金和材料结构非晶化的应用研究。

[1] Dong J, Peng HL*, Wang H, Tong Y*, Wang YT, Dmowski W, Egami T, Sun BA*, Wang WH & Bai HY*, Non-affine atomic rearrangement of glasses through stress-induced structural anisotropy. Nat. Phys. (2023). (中科院1区TOP, IF 19,  Highlighted in Rearranged under stress, New and Views, Nature Physics, Nov. 8, 2023).

[2] Dong J, Huan Y, Huang B, Yi J, Liu YH, Sun BA*, Wang WH & Bai HY*, Unusually thick shear-softening surface of micrometer-size metallic glasses. The Innovation 2(2), 100106 (2021). (中科院1区TOP, IF 33).

[3] Dong J, Huang Y, Zhang YB, Sun BA, Yang M, Wei XR, Lu ZC, Zhang F, Liang ZY, Zhao JK, Song WL, Wu Y, Lu ZP, Wang X-L, Ma D*, Anisotropic martensitic transformation in B2-CuZr-structured crystallites, Acta Mater. 289, 20872, (2025) (中科院1区TOP, IF 9).

[4] Huang Y# & Dong J#, Yang M, Zhang YB, Lu ZC, Wei XR, Zhao JK, Song WL, Liu XJ, Wang H, Zhang XB, Lu ZP, Wang X-L, Ma D*, Frictional shear stress-induced incomplete martensitic transformation in mono-crystalline B2-CuZr spherulites. Acta Mater.267, 119705 (2024). (中科院1区TOP, IF 9).

[5] Dong J, Shen J, Sun YH, Ke HB, Sun BA*, Wang WH & Bai HY*, Composition and size dependent torsion fracture of metallic glasses. J. Mater. Sci. Tech. 82, 153-160 (2021). (中科院1区TOP, IF 11).

[6] Dong J, Feng YH, Huan Y, Yi J, Wang WH, Bai HY* & Sun BA*, Rejuvenation in hot-drawn micrometer metallic glassy wires. Chin. Phys. Lett. 37(1), 017103 (2020). (中科院1区, IF 3, Highlighted by Physics World. https://physicsworld.com/a/making-metallic-glasses-more-plastic/).

[7] 董杰, 王雨田, 胡晶, 孙保安*, 汪卫华, 白海洋*. 非晶合金剪切带动力学行为研究. 力学学报52(2), 303-317 (2020).

[8] Dong J, Gao M, Huan Y*, Feng YH, Liu W & Wang WH, Enhanced tensile plasticity of Zr based bulk metallic glasses by a stress induced large scale flow. J. Alloy. Compd. 727, 297-303 (2017).

[9] Dong J, Huan Y*, Liu W, Feng YH, Dai YJ, Hao, SW. The influence of boundary conditions on modulus measurement in uniaxial compression tests. Exp. Tech. 41(3), 327-330 (2017).

[10] Chen J, Ren S*, Chen Z, Dong J*, Zhu L, Zhan Y, Wang W, Zeng S, Xiao J, Liang X & Ma, J*, Unveiling Irreversible β-Relaxations in Metallic Glasses via Electrical Resistivity. Metals, 15(2), 196 (2025).

[11] Gao M# & Dong J#, Huan Y, Wang YT & Wang WH*. Macroscopic tensile plasticity by scalarizating stress distribution in bulk metallic glass. Sci. Rep. 6, 21929 (2016).

[12] Wang YT, Dong J, Liu YH, Bai HY, Wang WH & Sun BA*. Optimum shear stability at intermittent-to-smooth transition of plastic flow in metallic glasses at cryogenic temperatures. Materialia 9, 100559 (2020).

[13] Yang, M., Zhang Y.B, Dong, J., Huang, Y., Lu, Z.C., Wang, L., Wei, X.R., Fu, Z.D., Zhao, J.K., Song, W.L., Li, W., Liu, Y.T., Ma, D. Developing centimeter-sized CuZr-based metallic glass composites via multi-element microalloying, Intermetallics 164, 108114 (2024).

[14] Zhou YB, Song WL, Zhang F, Wu Y, Lei ZF, Jiao MY, Zhang XB, Dong J, Zhang YB, Yang M, Lu ZC, Harjo S, Kawasaki T, Gong W, Zhao YC, Ma D*, Lu ZP, Probing deformation behavior of a refractory high-entropy alloy using in situ neutron diffraction, J. Alloy. Compd. 172635, (2023).

[15] Jiang XL, Song WL*, Yang M, Zhou YB, Huang Y, Lu ZC, Zhang YB, Dong J, Wang L, Peng B, Hu CM, Zhao JK, Kou ZS* & Ma D*.  Formation of novel TRIP-ductilized bulk metallic glass composites by manipulating nucleation kinetics via minor alloying. Rare Met. 42, 2182-2188 (2023).

[16] Zhang YB, Lu ZC,  Wang L, Yang M, Huang Y, Dong J, Wei XR, Song WL & Ma D*.

Eutectic growth kinetics as an indicator for glass-forming ability. Intermetallics 162, 108025 (2023).

[17] 赵燕春*, 姚文博, 董杰, 吕志超, 黄燕, 张艺波, 马东*, 杨铭*, Ti和Nb微合金化对CuZr基相变增韧非晶复合材料组织性能的影响,《有色金属工程》10, (2024).

[18] Liu MN, Hao Q, Dong J, Sun BA, Feng SD, Crespo D, Qiao JC*. Dynamic mechanical relaxation of behavior of binary metallic glasses. Intermetallics 130, 107705 (2021).

[19] Chen B, Yang R, Dong J, Wang SF, Wang J & Huan Y*, Development of in-situ SEM torsion tester for microscale materials. Measurement 139, 421-425 (2019).

[20] Liu W, Huan Y*, Dong J, Dai YJ & Lan D. A correction method of elasticmodulus in compression tests for linear hardening materials. MRS Commun. 5, 641-645. (2015).

[21] Gao M, Wang C, Dong J, Bai HY & Wang WH*. Macroscopic tensile plasticity of Zr-based bulk metallic glass with surface screw thread shaped structure. Mater. Sci. Eng. A 73, 417-422 (2016).

[22] Dai YJ, Huan Y*, Gao M, Dong J, Liu W, Pan MX, Wang WH & Bi ZL. Development of a high-resolution micro-torsion tester for measuring the shear modulus of metallic glass fibers. Meas. Sci. Technol. 26(2), 025902 (2015).

[23] Wang SF, Wang HC, Liu W, Feng YH, Chen B, Dong J, Jia HY & Huan Y*. Effect of deformation induced microstructure faults on the elastic mechanical parameters of micro-scale copper. Exp. Tech. 1(43), 1-6 (2018).

[24] Liu W, Huan Y*, Wang SF, Chen B, Dong J, Feng Y H, Lan D, Jia H Y, Verification of a novel micro-torsion tester based on electromagnetism using an improved torsion pendulum technique. Measurement 105, 41-44 (2017).

[25] 周振宇, 郇勇, 刘薇, 董杰. 石料力学性能分析在旧石器考古学研究中的应用.《人类学学报》35, 407-417 (2016).

[1] 董杰, 孙保安，白海洋，汪卫华. 一种非晶合金表面层剪切模量和层厚的测量方法及应用，发明专利 202010489694.5, 授权日2021-09-10; [2] 董杰, 郇勇, 高萌, 刘薇, 加海友,汪卫华.一种使金属玻璃产生拉伸塑性的加工处理方法. 发明专利 201510781725.3, 申请日 2015-11-13, 授权日 2017-05-31; [3] 高萌, 董杰, 赵德乾, 汪卫华，郇勇. 一种使韧性金属玻璃产生宏观拉伸塑性的方法. 发明专利 201610154260. X, 申请日 2016-03-18, 授权日 2018-01-19; [4] 郇勇, 刘薇, 董杰, 代玉静, 朱静静. 一种在金属材料压缩试验中修正弹性模量及应力-应变曲线的方法. 发明专利 201410825943.8, 申请日 2014-12-25, 授权日 2017-02-15; [5] 郇勇, 代玉静，董杰, 刘薇,毕贞龙.一种高分辨率电磁式微尺度扭转试验机及其试验方法.发明专利 201510115607.9, 申请日 2015-03-17, 授权日 2017-10-20; [6] 郇勇,加海友,刘薇,董杰,高萌,唐山.一种用于单轴材料试验机的双轴试验装置及试验方法.发明专利 201510932720.6, 申请日 2015-12-15, 授权日 2018-07-03; [7] 郇勇, 宋凡, 邵颖峰, 刘薇, 董杰, 加海友. 一种热震实验装置及其实验方法. 发明专利 201610035172.1, 申请日 2016-01-19, 授权日 2018-02-16; [8] 陈博，郇勇，喇高燕，宋凡，周谋望，王素芳，加海友，董杰. 一种测量单根肌肉纤维激力学行为的设备及测试方法. 发明专利 201710090123.2, 申请日 2017-02-20; [9] 陈博，郇勇，王素芳，杨荣，加海友，董杰，冯义辉. 一种在电镜下测量材料扭转性能横式测试装置及测试方法. 发明专利 201710361801.4, 申请日 2017-05-22; [10] 马东,张艺波,杨铭,董杰,黄燕,吕志超,魏学睿. 一种非晶复合材料及其制备方法. 发明专利2023110066466, 申请日2023-08-10. [11] 马东,黄燕,杨铭,董杰,张艺波,吕志超,魏学睿. 一种非晶复合材料及其制备方法. 发明专利2023109432029, 申请日2023-07-28. [12] 马东,杨铭,黄燕,董杰,张艺波,吕志超,赵金奎. 一种厘米级相变增韧非晶复合材料及其制备方法和应用. 发明专利202211388622.7, 申请日2022-11-08. [13] 马东,杨铭,黄燕,董杰,张艺波,吕志超,赵金奎. 一种非晶复合材料的高通量制备与表征方法. 发明专利2023105193122 申请日2023-05-09.