职称:教授
学位:博士
1. 专著和教材
[1] 叶爱君,管仲国编著,范立础主审:桥梁抗震(第三版),人民交通出版社, 2017.3
[2] 叶爱君,管仲国编著,范立础主审:桥梁抗震(第二版),人民交通出版社, 2011.9
[3] 叶爱君编著,范立础主审:桥梁抗震,人民交通出版社,2002.9
[4] 范立础、胡世德、叶爱君著:大跨度桥梁抗震设计,人民交通出版社,2001.5
2. 主要期刊论文(近10年)
[1] Wang Xiaowei, Alipour Alice, Wang Jingcheng, Shang Yu, and Ye Aijun*. (2023) “Seismic resonance behavior of soil-pile-structure systems with scour effects: Shake-table tests and numerical analyses.” Ocean Engineering. 283: 115052. https://doi.org/10.1016/j.oceaneng.2023.115052
[2] Zhou, L., Barbato, M., & Ye, A. * (2023). Pile Group Effect Modeling and Parametric Sensitivity Analysis of Scoured Pile Group Bridge Foundations in Sandy Soils under Lateral Loads, Journal of Bridge Engineering, 28(8), https://doi.org/10.1061/JBENF2.BEENG-586
[3] Wang Xiaowei, Luo Fuyuan, Ye Aijun*, “A holistic framework for seismic analysis of extended pile-shaft-supported bridges against different extents of liquefaction and lateral spreading.” Soil Dynamics and Earthquake Engineering; 170: 107914, 2023.107914
[4] Wang J, Wang X, Ye A*, Guan Z. Deformation-based pushover analysis method for transverse seismic assessment of inverted Y-shaped pylons in kilometer-span cable-stayed bridges: Formulation and application to a case study. Soil Dynamics and Earthquake Engineering; 2023; 169:107874
[5] Wang, J., Wang, X., Liu, T., Ye, A.*, Seismic uplift behavior and energy dissipation mechanism of scoured bridge pile-group foundations: Quasi-static test and numerical analysis. Ocean Engineering. 266, 2022.113172.
[6] Wang X, Liu T, Wang J, Ye A* , Weakened section detailing for scoured/elevated pile groups in sands toward post-earthquake resilient behavior: Quasi-static tests. Ocean Engineering; 266(P2) 2022: 112897.
[7] Lianxu Zhou, M. Shahria Alam, Aimin Song, and Aijun Ye*. Probability-based residual displacement estimation of unbonded laminated rubber bearing supported highway bridges retrofitted with Transverse Steel Damper. Engineering structures 272, 2022.115053.
[8] Lianxu Zhou, Aijun Ye*, and Fangyou Chen. Postearthquake Vertical Load-Carrying Capacity of Extended Pile Shafts in Cohesionless Soils: Quasi-Static Test and Parametric Studies. Journal of Bridge Engineering 27.8, 2022: 04022071.
[9] Zhou, L., Barbato, M., & Ye, A. *, Experimental Investigation of Postearthquake Vertical Load-Carrying Capacity of Scoured Reinforced Concrete Pile Group Bridge Foundations. Journal of Bridge Engineering, 2021,Vol.26(12)(入选ASCE-JBE Editor’s Choice)
[10] 周连绪,叶爱君,陈方有,镀锌铁丝约束混凝土应力-应变本构研究.土木工程学报, 2021, Vol.54(08)
[11] Liu T, Wang X, Ye A*. Roles of pile-group and cap-rotation effects on seismic failure mechanisms of partially-embedded bridge foundations: Quasi-static tests. Soil Dynamics and Earthquake Engineering, 2020.5,Vol.132
[12] Wang X, Ji B, Ye A*. Seismic behavior of pile-group-supported bridges in liquefiable soils with crusts subjected to potential scour: Insights from shake-table tests[J]. Journal of Geotechnical and Geoenvironmental Engineering, 2020, Vol.146(5)
[13] 周连绪, 叶爱君. 千米级斜拉桥横向减震体系振动台试验. 中国公路学报, 2019.9
[14] Wang X., Ye A.*, Shang Y., and Zhou L.. Shake-table investigation of scoured RC pile-group-supported bridges in liquefiable and nonliquefiable soils. Earthquake Engineering & Structural Dynamics, 2019.9, Vol.48(11)
[15] Wang X., Shafieezadeh A., and Ye A.*. Optimal EDPs for post-earthquake damage assessment of extended pile-shaft-supported bridges subjected to transverse spreading. Earthquake Spectra, 2019, Vol.35(3)
[16] Wang X., Ye A., and Ji B.. Fragility-based sensitivity analysis on the seismic performance of pile-group-supported bridges in liquefiable ground undergoing scour potentials”. Engineering Structures, 2019.11. Vol.198
[17] Wang X., Fang J., Zhou L., and Ye A.* Transverse seismic failure mechanism and ductility of reinforced concrete pylon for long span cable-stayed bridges: Model test and numerical analysis”. Engineering Structures, 2019.6, Vol.189
[18] Zhou L., Wang X., and Ye A.*. Low cycle fatigue performance investigation of Transverse Steel Dampers for bridges under ground motion sequences using shake-table tests. Engineering Structures, 2019.10, Vol.196
[19] Wang X., Ye A., Shafieezadeh A., and Padgett J.. Fractional order optimal intensity measures for probabilistic seismic demand modeling of extended pile-shaft-supported bridges in liquefiable and laterally spreading ground. Soil Dynamics and Earthquake Engineering,2019.2 Vol.120
[20] Blanco G., Ye A., Wang X., and Goicolea J. Parametric pushover analysis on elevated RC pile-cap foundations for bridges in cohesionless soils. Journal of Bridge Engineering, 2019, Vol.24(1)
[21] Zhou L., Wang X., and Ye A.*. Shake table test on transverse steel damper seismic system for long span cable-stayed bridges. Engineering Structures, 2019.1, Vol.179
[22] 王晓伟, 叶爱君, 商宇,砂土地基小直径单桩的浅层土p–y曲线. 岩土工程学报. 2018.9
[23] 叶爱君, 周连绪, 陈光,王晓伟. 大跨度斜拉桥倒Y形混凝土桥塔的横向拟静力试验. 土木工程学报. 2018.9
[24] 王晓伟, 叶爱君, 赫中营,砂土中桥梁高桩承台基础的抗震延性能力参数分析. 土木工程学报. 2018.5
[25] 王晓伟, 叶爱君, 李闯,可液化河谷场地不同形式梁式桥的地震反应. 同济大学学报. 2018.6
[26] Shang, Yu, Alipour, Alice, Ye, Aijun*, Selection of Input Motion for Seismic Analysis of Scoured Pile-Supported Bridge with Simplified Models. Journal of Structural Engineering. 2018, Vol.144(8).
[27] Wang, Xiaowei, Shafieezadeh, Abdollah, Ye, Aijun*. Optimal intensity measures for probabilistic seismic demand modeling of extended pile-shaft-supported bridges in liquefied and laterally spreading ground. Bulletin of Earthquake Engineering. 2018, Vol.16(1)
[28] Wang, Xiaowei, Ye, Aijun*, Shafieezadeh, Abdollah, et al. Shallow-Layer p-y Relationships for Micropiles Embedded in Saturated Medium Dense Sand Using Quasi-Static Test. Geotechnical Testing Journal, 2018, Vol.41(1)
[29] 叶爱君,方家欣,张少为,王晓伟,小箱梁桥横向减震体系及其耗能特性,中国公路学报,2017.12
[30] 商宇,叶爱君,王晓伟,冲刷条件下的桩基桥梁振动台试验,中国公路学报,2017.12
[31] Xing Shen,Xiaowei Wang,Qi Ye,Aijun Ye*; Seismic Performance of Transverse Steel Damper Seismic System for Long Span Bridges, Engineering structure, 2017.6, Vol.141(6)
[32] Wang X., Luo F., Su Z. and Ye A.* Efficient finite-element model for seismic response estimation of piles and soils in liquefied and laterally spreading ground considering shear localization [J]. ASCE International Journal of Geomechanics, 2017. Vol.17(6)
[33] He Z., Liu W., Wang X., and Ye A.*. Optimal force-based beam-column element size for reinforced concrete piles in bridges. Journal of Bridge Engineering, 2016, Vol.21(11)
[34] 刘腾飞,叶爱君,王晓伟,土体约束对桩柱式桥墩塑性铰长度的影响,同济大学学报,2016.12
[35] 沈星,倪晓博,叶爱君,大跨度斜拉桥边墩横向抗震体系研究,中国公路学报,2016.11, Vol.29(11)
[36] Xu Y., Shang Y. and Ye A.*. Dynamic interaction between bridge pier and its large pile foundation considering earthquake and scour depths. Advances in Structural Engineering, 2016.9, Vol.19(9)
[37] 王晓伟, 叶爱君, 罗富元. 液化场地桩柱式基础桥梁结构地震反应的敏感性分析. 工程力学, 2016. 8,Vol.33(5)
[38] 沈星,倪晓博,叶爱君,大跨度斜拉桥边墩新型横向钢阻尼器减震体系及设计方法,土木工程学报,2016.5,Vol.49(5)
[39] 王晓伟, 李闯, 叶爱君, 商宇. 可液化河谷场地简支梁桥的地震反应分析. 中国公路学报, 2016. Vol.29(4)
[40] 王晓伟, 叶爱君, 沈星, 庞于涛. 大跨度桥梁边墩横向减震体系的地震易损性分析. 同济大学学报, 2016. Vol.44(3)
[41] Wang X., Ye A.*, He Z., and Shang Y. Quasi-static cyclic testing of elevated RC pile-cap foundation for bridge structures. Journal of Bridge Engineering, 2016, Vol.21(2)
[42] Xing Shen; Alfredo Camara; Aijun Ye,Effects of Seismic Devices on Transverse Responses of Piers in the Sutong Bridge,Earthquake Engineering and Engineering Vibration,2015,Vol.14(4)
[43] 沈星,叶爱君,大跨度斜拉桥倒Y型混凝土主塔横向抗震性能分析,中国公路学报, 2015.11,Vol.28(11)
[44] 李闯,叶爱君,余茂峰,公路减隔震桥梁的地震反应简化分析,哈尔滨工程大学学报,2014.11,Vol.35(11)
[45] 沈星,倪晓博,叶爱君,2014.11,桥梁新型横向金属阻尼器研究,振动与冲击,2014.11,Vol.33(21)
[46] 王晓伟,赫中营,叶爱君,桥梁高桩承台基础地震破坏机理试验研究,同济大学学报,Vol.42(9),2014.9
[47] 赫中营,叶爱君,力法非线性梁柱单元的合理单元长度划分,工程力学, 2014.7, Vol.31(7)
[48] 沈星,叶爱君,王晓伟,双柱墩弹塑性位移能力简化计算方法,同济大学学报, 2014.4,Vol.42(4)
[49] A. Camara, M. A. Astiz and A. J. Ye, Fundamental Mode Estimation for Modern Cable-Stayed Bridges Considering the Tower Flexibility. Journal of Bridge Engineering,2014.6 Vol.19(6)
[50] 赫中营,叶爱君, 群桩效应对砂土地基中高桩承台群桩基础抗震性能的影响,土木工程学报, 2014.1,Vol.47(1)
[51] 叶爱君,何健,基于一体化模型的斜拉桥地震反应分析方法, 同济大学学报, 2013.9,Vol.41(9)
[52] 沈星,叶爱君,王晓伟. 柔性横系梁双柱墩的抗震行为分析,同济大学学报,2013.3,41(3)
[53] 赫中营, 叶爱君. 系梁对哑铃型高桩承台基础抗震性能影响. 振动与冲击,2013.1,Vol.32(1)
