（*为通讯作者，#为同等贡献）：

此处有时更新不及时，最新论文列表见 ‪Min Yi (易敏)‬ - ‪Google Scholar‬ 和 ResearchGate

1. C. Liang, Y. Yin, W. Wang, M. Yi*. A thermodynamically consistent non-isothermal phase-field model for selective laser sintering. International Journal of Mechanical Sciences, 2023, 259: 108602.
2. K. Li, W. Yang, Z. Shen, X. Zhang*, M. Yi*. Flexible graphene pressure sensor based on sponge sewn with cotton. Sensors and Actuators A: Physical, 2023, 354: 114266.
3. Z. Tang, Q. Gong*, M. Yi*. Spin-selective contact type and strong Fermi level pinning at a CrI3/metal interface. Materials Today Nano, 2023, 22: 100309.
4. H. Luo#, W. Tang#, Q. Gong*, M. Yi*. Giant enhancement of elastocaloric effect by introducing microstructural holes. Journal of Alloys and Compounds, 2023, 932: 167636.
5. 易敏*, 胡文轩. 晶体塑性模型及其在金属疲劳寿命预测中的应用. 南京航空航天大学学报, 2023, 55(1).
6. W. He, Y. Yin, Q. Gong*, M. Yi*, W. Guo. Giant magnetocaloric effect in magnets down to the monolayer limit. Small, 2023: 2300333.
7. W. Tang, Q. Gong, M. Yi*, B.-X. Xu, L.-Q. Chen. Thermodynamically Consistent Non-Isothermal Phase-Field Modelling of Elastocaloric Effect: Indirect vs Direct Method[J]. Available at SSRN 4399202.
8. Y. Yin, Q. Gong*, M. Yi*, W. Guo*. Emerging Versatile Two‐Dimensional MoSi2N4 Family. Advanced Functional Materials, 2022: 2214050.
9. M. Yi*, W. Wang, M. Xue, Q. Gong*, B.-X. Xu. Modeling and simulation of sintering process across scales. Archives of Computational Methods in Engineering, 2023, 30(5): 3325-3358.
10. W. Tang#, Z. Tang#, W. Lu, S. Wang, M. Yi*. Modeling and Prediction of Fatigue Properties of Additively Manufactured Metals. Acta Mechanica Solida Sinica, 2023, 36(2): 181-213.
11. X. Pan, L. Zhou*, C. Wang, K. Yu, Y. Zhu, M. Yi, L. Wang, S. Wen, W. He, X. Liang. Microstructure and residual stress modulation of 7075 aluminum alloy for improving fatigue performance by laser shock peening. International Journal of Machine Tools and Manufacture, 2023, 184: 103979.
12. 祝曼, 王阳, 刘强*, 易敏*. 复合材料II型疲劳分层扩展预测: 从应变能释放率-寿命(G-N)曲线到Paris' law. 复合材料学报, 2023, 40(9): 5433-5446
13. 朱熠奇, 殷艳, 周留成, 易敏*. 激光冲击铝合金微结构演化及力学行为的分子动力学模拟. 表面技术, 2022, 51(11): 1-9,57
14. Z. Zheng, M. Yi, S. Wang*. Abnormal trapping of hydrogen in the elastic stress field of dislocations in body-centered cubic iron. International Journal of Hydrogen Energy, 2022, 47(92): 39255-39264.
15. H. Cao, W. Lu, M. Yi, S. Wang*. Deformation and failure by weaving dislocation networks in body-centered-cubic tungsten. Materials & Design, 2022, 223: 111182.
16. M. Xue#, W. He#, Q. Gong*, M Yi, W. Guo. Nonlinear elasticity and strain-tunable magnetocalorics of antiferromagnetic monolayer MnPS₃. Extreme Mechanics Letters, 2022, 57: 101900.
17. H. Wang, G. Laskin, W. He, H. Boschker, M. Yi, J. Mannhart, PA. van Aken. Tunable Magnetic Anisotropy in Patterned SrRuO3 Quantum Structures: Competition between Lattice Anisotropy and Oxygen Octahedral Rotation. Advanced Functional Materials, 2022, 2108475.
18. D. Ohmer*, M. Yi*, O. Gutfleisch, B.-X. Xu. Phase-field modeling of paramagnetic austenite-ferromagnetic martensite transformation coupled with mechanics and micromagnetics. International Journal of Solids and Structures, 2022, 238: 111365.
19. 易敏*, 常珂, 梁晨光, 周留成, 易新, 胥柏香. 增材制造微结构演化及疲劳分散性计算. 力学学报, 2021, 53 (12): 3265- 3275.
20. Y. Yin, M. Yi*, W. Guo*. High and anomalous thermal conductivity in monolayer MSi₂Z₄ semiconductors. ACS Applied Materials & Interfaces, 2021, 13 (38): 45907-45915.
21. K. Li, W. Yang, M. Yi* and Z. Shen*. Graphene-based pressure sensor and strain sensor for detecting human activities. Smart Materials and Structures, 2021, 30:085027.
22. I. Dirba, M. Mohammadi, F. Rhein, Q. Gong, M. Yi, B.-X. Xu, M. Krispin, O. Gutfleisch. Synthesis and magnetic properties of bulk α″-Fe16N2/SrAl2Fe10O19 composite magnets. Journal of Magnetism and Magnetic Materials, 2021, 518:167414.
23. J. Wang, Z. Shen*, M. Yi*, X. Zhang. Muconic acid as high-performance organic anode for lithium ion batteries. Journal of Alloys and Compounds, 2021, 865:158573.
24. 杨阳祎玮, 易敏, 胥柏香. 粉末增材制造微结构的非等温相场模拟. 中南大学学报, 2020, 51(11):3019-3032.
25. Q. Gong, M. Yi*, B.-X. Xu. Electric field induced magnetization reversal in magnet/insulator nanoheterostructure. International Journal of Smart and Nano Materials, 2020, 11(3):298-309.
26. H. Wang, V. Srot, X. Jiang, M. Yi, Y. Wang, H. Boschker, R. Merkle, R. W. Stark, J. Mannhart, P. A. van Aken. Probing Charge Accumulation at SrMnO3/SrTiO3 Heterointerfaces via Advanced Electron Microscopy and Spectroscopy. ACS Nano, 2020, 14(10):12697–12707.
27. J. Wang, Z. Shen*, M. Yi*. Facile preparation of MoS₂/maleic acid composite as high-performance anode for lithium ion batteries. New Journal of Chemistry, 2020, 44(37):15887-15894.
28. J. Wang, Z. Shen*, M. Yi*. Scalable and High-Performance Graphene/Graphite Nanosheet Composite Anode for Lithium Ion Batteries via Jet Cavitation. Energy Technology, 2020, 8(10):2000511.
29. Q. Gong, M. Yi*, R. F. L. Evans, O. Gutfleisch, B.-X. Xu. Anisotropic exchange in Nd-Fe-B permanent magnets. Materials Research Letters, 2020, 8(3):89-96.      
30. D. Ohmer*, M. Yi*, M. Fries, O. Gutfleisch, B.-X. Xu. Calculating the magnetocaloric effect in second-order-type material by micromagnetic simulations: A case study on Co₂B. Scripta Materialia, 2020, 177:218-222.      
31. W.-B. Yu, Z.-Y. Hu, J. Jin, M. Yi, M. Yan, et al. Unprecedented and highly stable lithium storage capacity of (001) faceted nanosheet-constructed hierarchically porous TiO2/rGO hybrid architecture for high-performance Li-ion batteries. National Science Review, 2020, 7(6):1046-1058.      
32. Y. Yang, P. Kühn, M. Yi, H. Egger, B.-X. Xu. Non-isothermal phase-field modeling of heat–melt–microstructure-coupled processes during powder bed fusion. JOM, 2020, 72:1719-1733.      
33. X. Zhang, Z. Shen, W. Zhang, M. Yi, H. Ma, L. Liu, L. Liu, Y. Zhao. Graphene coating for dnhancing the atom oxygen erosion resistance of Kapton. Coatings, 2020, 10(7): 644.
34.  Y. Yang, O. Ragnvaldsen, Y. Bai, M. Yi*, B.-X. Xu*. 3D non-isothermal phase-field simulation of microstructure evolution during selective laser sintering. npj Computational Materials, 2019, 5:81.      
35. M. Yi*, B.-X. Xu, O. Gutfleisch. Computational study on microstructure evolution and magnetic property of laser additively manufactured magnetic materials. Computational Mechanics, 2019, 64(4):917-935.      
36. Q. Gong, M. Yi*, B.-X. Xu. Multiscale simulations toward calculating coercivity of Nd-Fe-B permanent magnets at high temperatures. Physical Review Materials, 2019, 3(8): 084406.      
37. J. Wang, Z. Shen*, M. Yi*. Liquid-exfoliated graphene as highly efficient conductive additives for cathodes in lithium ion batteries. Carbon, 2019, 153:156-163.
38. J. Wang, Z. Shen*, M. Yi*. Hydraulic compaction on electrode to improve volumetric energy density of LiFePO4/graphite battery. Industrial & Engineering Chemistry Research, 2019, 58 (34): 15407-15415.
39.  J. Wang, Y. Zhang, M. Yi*, Z Shen*, et al. Coating LiFePO₄ with conductive nanodots by magnetron sputtering: towards high-performance cathode for lithium-ion batteries. Energy Technology, 2019, 7(3):1800634.      
40.  J. Wang, M. Yi*, Z. Shen*, L. Liu, X. Zhang, S. Ma. Enhanced thermal and mechanical properties of poly (vinylidene fluoride) nanocomposites reinforced by liquid-exfoliated graphene. Journal of Macromolecular Science, Part A 2019, 56 (7):733-740.      
41. Q. Gong, M. Yi*, R.F.L. Evans, B.-X. Xu, O. Gutfleisch. Calculating temperature-dependent properties of permanent magnets by atomistic spin model simulations. Physical Review B 2019, 99 (21):214409.      
42.  M. Yi, B.-X. Xu, R. Müller, D. Gross. Strain-mediated magnetoelectric effect for the electric-field control of magnetic states in nanomagnets. Acta Mechanica, 2019, 230 (4), 1247-1256.      
43.  L. Molina-Luna, S. Wang, Y. Pivak, A. Zintler, H. Pérez-Garza, R. Spruit, Q. Xu, M. Yi, B.-X. Xu, M. Acosta. Enabling nanoscale flexoelectricity at extreme temperature by tuning cation diffusion. Nature Communications, 2018, 9: 4445.    
44. S. Sawatzki, T. Schneider, M. Yi, et al. Anisotropic local hardening in hot-deformed Nd-Fe-B permanent magnets. Acta Materialia, 2018, 147:176-183.      
45. S. Sabet, A. Moradabadi, S. Gorji, M. Yi, et al. Impact of interface structure on magnetic exchange coupling in MnBi/Fe_xCo_{1- x} bilayers. Physical Review B, 2018, 98 (17):174440.      
46. Z. Gao, Z. Hao, M. Yi, Y. Huang, et al. Correlation between mechanical strength of amorphous TiO₂ nanotubes and their solid state crystallization pathways. ChemistrySelect, 2018, 3:10711-10716.      
47. M. Duerrschnabel^#, M. Yi^#, K. Uestuener, et al. Atomic structure and domain wall pinning in samarium-cobalt based permanent magnets. Nature Communications, 2017, 8:54. [M.D. and M.Y. contributed equally to the joint experimental and theoretical work]      
48. M. Yi, H. Zhang, B.-X. Xu. Voltage-driven charge-mediated fast 180 degree magnetization switching in nanoheterostructure at room temperature. npj Computational Materials, 2017, 3:38.      
49. M. Yi, H. Zhang, O. Gutfleisch, et al. Multiscale examination of strain effects in Nd-Fe-B permanent magnets. Physical Review Applied, 2017, 8 (1):014011.      
50. T. Helbig, K. Loewe, S. Sawatzki, M. Yi, et al. Experimental and computational analysis of magnetization reversal in (Nd,Dy)-Fe-B core shell sintered magnets. Acta Materialia, 2017, 127:498-504.      
51. H. Liu, L. Liu, M. Yi*, et al. Liquid-exfoliated MoS₂ nanosheets/graphene composites with high capacity and excellent cycle stability for lithium-ion batteries. Chemical Engineering Journal, 2017, 311:293-301.      
52. H. Sun, M. Yi*, Z. Shen, et al. Developing a new controllable lunar dust simulant: BHLD20. Planetary and Space Science, 2017, 141:17-24.
53. Y. Zhang, H. Ma, M. Yi*, et al. Magnetron-sputtering fabrication of noble metal nanodots coated TiO₂ nanoparticles with enhanced photocatalytic performance. Materials & Design, 2017, 125:94-99.      
54. H. Liu, M. Yi*, L. Liu, et al. Self-stacked nanomaterial of small-sized MoS₂ nanosheets for high-performance lithium-ion batteries. Energy Technology, 2017, 5:1-8.      
55. H. Ma, Z. Shen, M. Yi, et al. Direct exfoliation of graphite in water with addition of ammonia solution. Journal of Colloid and Interface Science, 2017, 503:68-75.      
56. M. Yi, O. Gutfleisch, and B.-X. Xu. Micromagnetic simulations on the grain shape effect in Nd-Fe-B magnets. Journal of Applied Physics, 2016, 120:033903.      
57. M. Yi and B.-X. Xu. A real-space and constraint-free phase field model for the microstructure of ferromagnetic shape memory alloys. International Journal of Fracture, 2016, 202(2):179-194.      
58. S. Wang, M. Yi*, and B.-X. Xu. A phase-field model of relaxor ferroelectrics based on random field theory. International Journal of Solids and Structures, 2016, 83:142-153.      
59. M. Yi and Z. Shen. Fluid dynamics: an emerging route for the scalable production of graphene in the last five years. RSC Advances. 2016,6:72525-72536.      
60. M. Yi and Z. Shen. A review on mechanical exfoliation for scalable production of graphene. Journal of Materials Chemistry A. 2015, 3(22):11700-11715.      
61. M. Yi, B.-X. Xu, and Z. Shen. Effects of magnetocrystalline anisotropy and magnetization saturation on the mechanically induced switching in nanomagnets. Journal of Applied Physics. 2015, 117:103905.      
62. M. Yi, B.-X. Xu and D. Gross. Mechanically induced deterministic 180^o switching in nanomagnets. Mechanics of Materials. 2015,87:40-49.      
63. M. Yi, B.-X. Xu and Z. Shen. 180^o magnetization switching in nanocylinders by a mechanical strain. Extreme Mechanics Letters. 2015, 3:66-71.      
64. M. Yi, Z. Shen, L. Liu, et al. Size-selected boron nitride nanosheets as oxygen-atom corrosion resistant fillers. RSC Advances. 2015, 5:2983-2987.    
65. M. Yi and Z. Shen. Kitchen blender for producing high-quality few-layer graphene. Carbon. 2014, 78:622-626.      
66. M. Yi, Z. Shen, X. Zhao, et al. Exploring few-layer graphene and graphene oxide as fillers to enhance the oxygen-atom corrosion resistance of composites. Physical Chemistry Chemical Physics. 2014, 16:11162-11167.      
67. M. Yi, Z. Shen, X. Zhao, et al. Boron nitride nanosheets as oxygen-atom corrosion protective coatings. Applied Physics Letters. 2014, 104:143101.      
68. M. Yi and B.-X. Xu. A constraint-free phase field model for ferromagnetic domain evolution. Proceedings of the Royal Society A-Mathematical Physical and Engineering Sciences. 2014, 2171:20140517(p1-p19).      
69. M. Yi, Z. Shen, X. Zhang, et al. Achieving concentrated graphene dispersions in water/acetone mixtures by the strategy of tailoring Hansen solubility parameters. Journal of Physics D: Applied Physics. 2013, 46:025301.      
70. M. Yi, Z. Shen, W. Zhang, et al. Hydrodynamics-assisted scalable production of boron nitride nanosheets and their application in improving oxygen-atom erosion resistance of polymeric composites. Nanoscale. 2013, 5:10660-10667.
71. M. Yi, Z. Shen, S. Liang, et al. Water can stably disperse liquid-exfoliated graphene. Chemical Communications. 2013, 49:11059-11061.
72. M. Yi, J. Li, Z. Shen, et al. Morphology and structure of mono- and few-layer graphene produced by jet cavitation. Applied Physics Letters. 2011, 99:123112.     
73. M. Yi, W. Zhang, Z. Shen, et al. Controllable functionalization and wettability transition of graphene-based films by an atomic oxygen strategy. Journal of Nanoparticle Research. 2013, 15:1-14.      
74. M. Yi, Z. Shen, S. Ma, et al. A mixed-solvent strategy for facile and green preparation of graphene by liquid-phase exfoliation of graphite. Journal of Nanoparticle Research. 2012, 14:1-9.      
75. M. Yi, Z. Shen, X. Zhang, et al. Vessel diameter and liquid height dependent sonication-assisted production of few-layer graphene. Journal of Materials Science. 2012, 47:8234-8244.      
76. M. Yi, Z. Shen and J. Zhu. A fluid dynamics route for producing graphene and its analogues. Chinese Science Bulletin. 2014, 59:1794-1799.      
77. M. Yi, S. Liang, L. Liu, et al. Investigating the nature of graphene-based films prepared by vacuum filtration of graphene dispersions. Journal of Nanoscience and Nanotechnology. 2014, 14:4969-4975.      
78. 易敏，沈志刚，郭瑶峰. 具有初始随机材料缺陷的非晶合金剪切带模拟. 北京航空航天大学学报, 2012, 38 (7):936-940.      
79. S. Liang, Z. Shen, M. Yi, et al. In-situ exfoliated graphene for high-performance water-based lubricants. Carbon. 2016, 96:1181-1190.      
80. S. Wang, M. Yi, and Z. Shen. The effect of surfactants and their concentration on the liquid exfoliation of graphene. RSC Advances. 2016,6:56705-56710.      
81. S. Liang, Z. Shen, M. Yi, et al. Stable aqueous dispersion of exfoliated graphene for tribological applications. Journal of Nanoscience and Nanotechnology. 2016, 16:1491-1497.      
82. S. Wang, M. Yi, Z. Shen, et al. Adding ethanol can effectively enhance the graphene concentration in water/surfactant solutions. RSC Advances. 2014, 4:25374-25378.      
83. J. Li, M. Yi, Z. Shen, et al. Experimental study on a designed jet cavitation device for producing two-dimensional nanosheets. Science China Technological Sciences. 2012, 55:2815-2819.      
84. W. Zhang, M. Yi, Z. Shen, et al. Graphene-reinforced epoxy resin with enhanced atomic oxygen erosion resistance. Journal of Materials Science. 2013, 48:2416-2423.      
85. S. Liang, M. Yi, Z. Shen, et al. One-step green synthesis of graphene nanomesh by fluid-based method. RSC Advances. 2014, 4:16127-16131.      
86. Z. Shen, J. Li, M. Yi, et al. Preparation of graphene by jet cavitation. Nanotechnology. 2011, 22:365306.      
87. L. Liu, Z. Shen, M. Yi, et al. A green, rapid and size-controlled production of high-quality graphene sheets by hydrodynamic forces. RSC Advances. 2014, 4:36464-36470.      
88. S. Liang, Z. Shen, M. Yi, et al. Journal of Nanoscience and Nanotechnology. 2015, 15:2686-2694.      
89. B. Chen, Y. Li, M. Yi, et al. Optimization of mechanical properties of bulk metallic glasses by residual stress adjustment using laser surface melting. Scripta Materialia. 2012,66:1057-1060.      
90. 张雯，易敏，沈志刚，赵小虎. 氧化物涂层对航天器材料原子氧剥蚀的防护. 北京航空航天大学学报, 2013, 39 (8):1074-1078.
91. 张雯，易敏，沈志刚，张晓静. 石墨烯用于提高材料抗原子氧剥蚀性能. 北京航空航天大学学报, 2014, 40 (2):172-176.      
92. L. Liu, Z. Shen, Y. Zheng, M. Yi, et al. Boron nitride nanosheets with controlled size and thickness for enhancing mechanical properties and atomic oxygen erosion resistance. RSC Advances. 2014, 4:37726-37732.      
93. L. Liu, Z. Shen, S. Liang, M. Yi, et al. Graphene for reducing bubble defects and enhancing mechanical properties of graphene/cellulose acetate composite films. Journal of Materials Science. 2014, 49:321-328.      
94. L. Liu, Z. Shen, S. Liang, M. Yi, et al. Enhanced atomic oxygen erosion resistance and mechanical properties of graphene/cellulose acetate composite films. Journal of Applied Polymer Science. 2014, 131: 40292.