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力学系

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副高级职称（按拼音排序）

姚寅

所在学科：力学

联系电话：010-68918982、15210462837

通讯地址：北京理工大学宇航楼313

职称：长聘副教授

邮箱：yaoyin@bit.edu.cn

邮编：100081

教育经历

2004年9月-2010年10月，在南京航空航天大学获得固体力学专业博士学位
2000年9月-2004年6月，在南京航空航天大学获得土木工程专业学士学位

工作经历

2021年9月-至今，北京理工大学，长聘副教授
2017年5月-2021年8月，北京理工大学，预聘助理教授
2013年7月-2017年4月，中国科学院力学研究所，助理研究员
2010年12月-2013年6月，中国科学院力学研究所，博士后

主要研究领域

1、微纳米材料力学
2、先进复合材料力学
3、软物质力学
4、功能柔性材料设计和制备

获奖情况

1、中国力学学会自然科学一等奖，微纳尺度表界面效应的表征理论及应用，2022，排名3/3

社会兼职

近年来主要发表论文

[1] Z.Y. Yu, P.R. Li, Z.L. Peng, Y. Yao*, S.H. Chen*, How to select discrete or continuous interfaces in biological materials to achieve a strength-toughness tradeoff. J. Mech. Phys. Solids, 2024, 183, 105502.
[2] S. Xiao, H. Wu, Z.L. Peng, Y. Yao*, S.H. Chen*, Surface effect on the partial-slip contact of a nano-sized flat indenter. Mech. Mater., 195,105057.
[3] P.R. Li, Z.Y. Yu, Z.L. Peng, Y. Yao*, S.H. Chen*, A data-driven simple design of single-level nacreinspired composites with high strength and toughness. Mech. Adv. Mater. Struct., 2024, 31(13), 2889-2900.
[4] J.N. Huang, D.W. Li, Z.L. Peng, B. Zhang, Y. Yao*, S.H. Chen*, High-Efficient Anti-Icing Deicing Method Based on Graphene Foams. ACS Appl. Mater. Interfaces, 2023, 15,43026-43037.
[5] Z.Y. Yu, P.R. Li, Y. Yao*, S.H. Chen*, An alternative shear lag model for composites with discrete interfaces. Mech. Mater., 176, 104530.
[6] S. Xiao, Z.L. Peng, H. Wu, Y. Yao*, S.H. Chen*, Surface Effect in Nano-Scale Fretting Contact Problems. ASME J. Appl. Mech., 2023, 90, 111005.
[7] P.R. Li, Z.Y. Yu, Z.L. Peng, B. Zhang, Y. Yao*, S.H. Chen*, Influence of bone teeth on strength and toughness of sutured bone plate of turtle shell. Acta Mech. Sin., 39(10), 623097.
[8] J.N. Huang, D.W. Li, Z.L. Peng, B. Zhang, Y. Yao*, S.H. Chen*, A new method based on the shear lag model for accurate determination of ice adhesion shear strength on solid surface. Sci. China Technol. Sci., 2023, 66(4),987-997.
[9] H.X. Ban, Y. Yao*, The coupling effects of strain gradient and damage on Mode I crack tip stress fields. Theor. Appl. Fract. Mech., 2023, 126. 103989.
[10] J. Liu, Y. Yao*, S.H. Chen*, X.H. Li*, Z.J. Zhang, A strong and reversible adhesive fibrillar surface based on an advanced composite with high strength and strong adhesion. Int. J. Smart Nano Sci., 14(1), 103-121.
[11] Y. Yao, J.H. Chen, J. Liu, S.H. Chen*, An alternative constitutive model for elastic particle-reinforced hyperelastic matrix composites with explicitly expressed Eshelby tensor. Compos. Sci. Technol., 2022, 221, 109343.
[12] Y. Yao, S.H. Chen, Z.P. Huang*, A generalized Ogden model for the compressibility of rubber-like solids. Philos. Trans. R. Soc. A, 2022, 380(2234): 20210320.
[13] J.H. Chen, Y. Yao*, B. Zhang*, The interface debonding in particle-reinforced nonlinear viscoelastic polymer composites. Meccanica, 57(6), 1353-1367.
[14] J. Liu, Y. Yao*, S.H. Chen*, X.H. Li*, Z.J. Zhang, A new nanoparticle-reinforced silicone rubber composite integrating high strength and strong adhesion. Compos. Part A, 2021, 151, 106645.
[15] J.H. Chen, J. Liu, Y. Yao*, Z.L. Peng, S.H. Chen*, The microscopic mechanism of size effect in silica-particle reinforced silicone rubber composites. Eng. Fract. Mech., 2021, 255, 107945.
[16] N. Jia, Z.L. Peng, J.J. Li, Y. Yao*, S.H. Chen*. Dispersive behavior of high frequency Rayleigh waves propagating on an elastic half space. Acta Mech. Sin., 2021, 37(4), 562-569.
[17] 郭晓龙，姚寅*，陈少华*, 一种预测颗粒增强复合材料界面力学性能的新方法. 力学学报, 2021, 53(5), 1334-1344.
[18] H.X., Ban, Z.L. Peng, D.N. Fang, Y. Yao*, S.H. Chen*, A modified conventional theory of mechanism-based strain gradient plasticity considering both size and damage effects. Int. J. Solids Struct., 2020, 202, 384-397.
[19] J. Liu, Y. Yao*, X.H. Li*, Z.J. Zhang, Fabrication of advanced polydimethylsiloxane based functional materials: Bulk modifications and surface functionalizations. Chem. Eng. J., 2020, 408, 127262.
[20] J.H. Chen, J. Liu, Y. Yao*, Z.L. Peng, S.H. Chen*, Effect of microstructural damage on the mechanical properties of silica nanoparticle-reinforced silicone rubber composites. Eng. Fract. Mech., 2020, 235, 107195.
[21] Y. Yao, Z.L. Peng, J.J. Li, S.H. Chen*, A new elastic theory of nanocomposites with incoherent interface effect based on interface energy density. ASME J. Appl. Mech., 2020, 87(2), 021008.
[22] N. Jia, Z.L. Peng, Y. Yao*, S.H. Chen*, A surface energy density-based theory of nanoelastic dynamics and its application in the scattering of P-wave by a cylindrical nanocavity. ASME J. Appl. Mech., 2020, 87(10), 101001.
[23] N. Jia, Z.L. Peng, S. Wang, J.J. Li, Y. Yao*, S.H. Chen*, Surface and chemical diffusion effects of nanowire electrodes in lithium-ion batteries. Sci. China-Technol. Sci., 2020, 63(11), 2413-2422.
[24] N. Jia, Z.L. Peng, Y.Z. Yang, Y. Yao*, S.H. Chen*, The coupling effect of surface effect and chemical diffusion in lithium-ion battery with spherical nanoparticle electrodes. Int. J. Appl. Mech., 2020, 12(8), 2050091.
[25] Y.X. Xie, J.J. Li, Z.L. Peng, Y. Yao*, S.H. Chen*, A first-principle study on the atomic-level mechanism of surface effect in nanoparticles. Mater. Today Commun., 2020, 24, 100948.
[26] H.X., Ban, Y. Yao*, S.H. Chen*, D.N. Fang, A new constitutive model of micro-particle reinforced metal matrix composites with damage effects. Int. J. Mech. Sci., 2019, 152, 524-534.
[27] Z.L. Peng, H.B. Yin, Y. Yao*, S.H. Chen*, Effect of thin-film length on the peeling behavior of film-substrate interfaces. Phys. Rev. E, 2019, 100(3), 032804.
[28] D.H. Li, Y. Yao*, An approximate method to predict the mechanical properties of small volume fraction particle-reinforced composites with large deformation matrix. 2019, Acta Mech., 230(9), 3307-3315.