2002.9-2008.8，密歇根大学(安娜堡), 土木与环境工程系，工学博士

1997.9-2000.3，东南大学，道路与铁道工程，工学硕士

1993.9-1997.7，长安大学，公路与城市道路工程，工学学士

本科生课程：建筑材料（英）（40030902）

本科生课程：建筑材料（40030352-0）

本科生课程：未来交通（英）（00030272-90）

2020年，国家级人才计划奖励

2020年，中国公路学会科学技术一等奖，1/15

2019年，河南省科技进步一等奖，4/15

2019年，交通运输行业中青年科技创新领军人才

2018年，云南省科学技术进步二等奖，1/12

2016年，云南省科学技术进步二等奖，3/12

2015年，国家科技进步二等奖，6/15

2015年，中国公路学会科学技术一等奖，3/15

2015年，中国公路青年科技奖

2015年，中国硅酸盐学会青年科技奖

2014年，国家技术发明二等奖，5/6

2013年，中国公路学会科学技术一等奖，9/15

用于交通基础设施的超高性能水泥基材料、智能材料的研发；水泥基材料多尺度力学表征与模拟；水泥路面结构优化设计与服役能力提升；路面传感监测与低成本、快速修复技术；大跨径钢桥面铺装体系力学分析与结构优化设计。

Cement and Concrete Composites (SCI), Associate editor

ASCE Nanomechanics and Micromechanics Committee, Chair

World Transport Convention (世界交通大会)，学科主席

中国公路学会青年专家委员会，副秘书长

Frontiers of Structural and Civil Engineering (SCI), Editorial board member

Journal of Sustainable Cement-based Materials (SCI), Editorial board member

Road Materials and Pavement Design (SCI), Editorial board member

International Journal of Pavement Research and Technology (EI), Editorial board member

Innovations in characterization and modeling of road materials and pavements, Guest Editor

建筑材料学报(EI)，编委

中国公路学报(EI)，编委

陆地交通气象灾害防治技术国家工程实验室技术委员会，委员

中国硅酸盐学会测试技术分会，理事

中国公路学会道路工程分会，理事

1.国家重点研发计划课题，传感器与公路基础设施协调耦合与工艺适配技术研究（2021.12-2024.12），在研，主持

2.国家重点研发计划子课题，重大公路基础设施安全服役性能监测智能传感器研发（2021.12-2024.12），在研，主持

3.国家自然科学基金面上项目，复杂环境、动载及高度夹杂条件下UHPC路面材料破损机理及设计方法（2021.01-2024.12），在研，主持

4.重点实验室基金，利用足尺加速加载试验装置开展智能路面材料及技术评估（2020.09-2022.09），在研，主持

5.国家重点研发计划子课题，智能道路铺装结构系统集成技术及系统设计理论体系（2019.01-2022.12），在研，主持

6.国家自然科学基金面上项目，混凝土持续加载下细观力学过程与宏观构件徐变性能综合研究（2018.01-2021.12），结题，主持

7.国家重点研发计划子课题，基于激光扫描和三维映射技术的路面桥梁关键计量测试技术与装备研究（2017.07-2020.12），结题，主持

8.重点实验室基金，高寒高海拔地区早强抗冻混凝土性能与机理研究（2017.01-2018.12），结题，主持

9.国家自然科学基金面上项目，水泥混凝土微观徐变试验与理论研究（2016.01-2019.12），结题，主持

10.交通运输部重点项目，沥青路面压电技术与设备集成研究（2014.01-2017.12），结题，主持

11.国家自然科学基金青年项目，基于C-S-H凝胶的水泥混凝土俆变机理及多级预测模型研究（2012.01-2014.12），结题，主持

12.教育部博士学科点新教师基金，经预湿处理轻细骨料提高混凝土铺面材料抗盐冻性机理研究（2012.01-2014.12），结题，主持

专著：

1. 魏亚，梁思明，封基梁《农村公路水泥混凝土路面设计施工及养护》，人民交通出版社，2019

2. 魏亚，《水泥混凝土路面设计指南》，人民交通出版社，2014

近期期刊论文：

1.Liu, Ch., Wei, Y.*, Experimental study on interface performance between implantable cement-based sensor and matrix concrete, Construction and Building Materials, 354 (2022) 128316.

2.Ye, Zh., Wei, Y., Wang, W., Wang, L.* An efficient real-time vehicle monitoring method, IEEE Transactions on Intelligent Transportation System, doi: 10.1109/TITS.2022.3150224.

3.Cui, Y., Wei, Y.*, Mixed "ionic-electronic" thermoelectric effect of reduced graphene oxide reinforced cement-based composites, Cement and Concrete Composites, 2022, 128 (104442).

4.Liu, Y., Wei, Y.*, Drop-weight impact resistance of ultra-high performance concrete and the corresponding statistical analysis, ASCE’s Journal of Materials in Civil Engineering, 2022, 34(1): 04021409.

5.Guo, W., Huang, X., Zhao, L., Wei, Ya*. Transverse Cracking of Concrete Base Plate in CRTS III Ballastless Track Structure: Effects of Environmental Boundary Conditions, Applied Sciences, 2021, 11(21), 10400.

6.Liu, Y., Wei, Y. *, Internal curing efficiency and key properties of UHPC influenced by dry or prewetted calcined bauxite aggregate with different particle size, Construction and Building Materials, 312 (2021) 125406.

7.Wang, H., Ma, J., Yang, H., Sun, F., Wei, Y., and Wang, L. *, Development of three-dimensional pavement texture measurement technique using surface structured light projection, Measurement, 2021, 185, 110003.

8.Liu, Y., Wei, Y. *, Abrasion resistance of ultra-high performance concrete with coarse aggregate, Materials and Structures, 2021, 54 (4)-157.

9.Yang, H., Wei, Y., Zhang, W., Ai, Y., Ye, Zh., and Wang, L. *, Development of piezoelectric energy harvester system through optimizing multiple structural parameters, Sensors, 2021, 21 (8), DOI 10.3390/s21082876.

10.Ye, Zh., Yan, G., Wei, Y., Xiao, Y., Zhou, B., Li, N. and Wang, L.*, Real-time and efficient traffic information acquisition via pavement vibration IoT monitoring system, Sensors, 2021, 21 (8), https://doi.org/10.3390/s21082679.

11.Yan, Ch., Wei, Y.*, Xiao, Y., and Wang, L., Pavement 3D data denoising algorithm based on gridded ellipsoid detection, Sensors, 2021, 21 (7), DOI10.3390/s21072310.

12.Wei, Y.*, Kong, W., and Wang, Y., Strengthening mechanism of fracture properties by nano materials for cementitious materials subject to early-age frost attack, Cement and Concrete Composites, 2021, 119 (104025).

13.Liu, Y., Wei, Y. *, Effect of calcined bauxite powder or aggregate on the shrinkage properties of UHPC, Cement and Concrete Composites, 2021, 118: 103967.

14.Wei, Y.*, Yan, C., Xiao, Y., and Wang, L., Methodology for quantifying features of early-age concrete cracking from laser scanned 3D data, Journal of Materials in Civil Engineering, 2021, 33 (7), 04021151.

15.Wei, Y.*, Kong, W., Wang, Y., and Sha, Ai, Multifunctional Application of Nanoscratch Technique to Characterize Cementitious Materials, Cement and Concrete Research, 2021, (140), 106318.

16.Yang, Z., Wei, Y., and Wang, L.* Modelling and characterizing the adhesion of parallel-grooved interface between concrete lining structure and geopolymer by wedge splitting method, Mathematical Problems in Engineering, 2020, Doi.org/10.1155/2020/2507062.

17.Kong, W., Wei, Y.*, Wang, Y., and Sha, Ai, Development of Micro and Macro Fracture Properties of Cementitious Materials Exposed to Freeze-thaw Environment at Early Ages, Construction and Building Materials, 2021 (271):121502.

18.Liu, Y., Wei, Y. *, Guo Weiqiang, Effect of filler type, fineness and shape on the properties of non-fibrous UHPC matrix, ASCE’s Journal of Materials in Civil Engineering, 2021, 33(5): 04021084.

19.Qian, Zh. *, Ren, H., Wei, Y., Effect of aggregate gradation and morphology on porous asphalt mixture performance, ASCE’s Journal of Materials in Civil Engineering, 2021, 33(5): 04021055.

20.Xiao, Y., Wei, Y.*, Yan, Ch., Liu, Y., Wang, L. A new data preprocessing method for 3D reconstruction of pavement. International Journal of Pavement Engineering, 2021, 22(6): 675-689. DOI: 10.1080/10298436.2019.1634270.

21.Liu, Y., Wei, Y. *, Internal curing by porous calcined bauxite aggregate in ultra-high performance concrete, ASCE’s Journal of Materials in Civil Engineering, ASCE’s Journal of Materials in Civil Engineering, 2021, 33(3): 04020497.

22.Chen, L., Qian, Zh.*, Chen, D., Wei, Y., Feasibility evaluation of a long-life asphalt pavement for steel bridge deck, Advances in Civil Engineering, 2020, https://doi.org/10.1155/2020/5890945.

23.Liang, S., Wei, Y.*, Effect of water-to-cement ratio and curing age on microscopic creep and creep recovery of hardened cement pastes by microindentation, Cement and Concrete Composites, 113 (2020) 103619.

24.Huang, W., Pei, M., Liu, X., Yan, Ch, and Wei, Y.*, Nonlinear Optimization of Orthotropic Steel Deck System Based on Response Surface Methodology, Research, Doi: 10.34133/2020/1303672,2020.

25.Liang, S., Wei, Y.*, New insights into creep and creep recovery of hardened cement paste at micro scale, Construction and Building Materials, 2020, (248), 118724.

26.Wei, Y.*, Guo, W., Wu, Z, and Gao, X., Computed permeability for cement paste subject to freeze-thaw cycles at early ages, Construction and Building Materials, 2020, 244, 118298.

27.Liang, S., Wei, Y.*, Imperfect interface effect on creep property of hardened cement pastes: Investigation from nano to micro scales, ASCE’s Journal of Materials in Civil Engineering, 2020, 32(7): 04020173.

28.Huang, W., Pei, M., Liu, X. and Wei, Y.*, Design and construction of super-long span bridges in China: Review and future perspectives, Frontiers of Structural and Civil Engineering, 2020, 14(4):803-838.

29.Huang, W., Liang, S., Wei, Y.*, Surface deflection-based reliability analysis of asphalt pavement design, Science China Technological Science, 2020, 63 (9), 1824-1836.

30.Wei, Y.*, Guo, W., and Zhang, Q., A model for predicting evaporation from fresh concrete surface during the plastic stage, Drying Technology, 2020, 38(16): 2231-2241.

31.Liang, S., Wei, Y.*, Gao, Xiang, and Qian, Zhendong, Effect of epoxy impregnation on characterizing microstructure and micro-mechanical properties of concrete by different techniques, Journal of Materials Science, 2020, 55: 2389-2404.

32.Wu, Z., Wei, Y.*, Wang, S., Chen, J., Wang, Y. Application of X-ray micro-CT for quantifying degree of hydration of slag-blended cement paste. ASCE’s Journal of Materials in Civil Engineering, 2020, 32(3): 04020008.

33.Huang, W., Guo, W., Wei, Y.*, Prediction of paving performance for epoxy asphalt mixture by its time and time-dependent properties, ASCE’s Journal of Materials in Civil Engineering, 2020, 32(3):04020017-1-12.

34.Wei, Y.*, Liang, Siming, Gao, X., and Feng, J., Design and Construction of Low-volume Road: Experiences from China, Road Materials and Pavement Design, 2020, 21(2): 393-410.

35.Wei, Y.*, Huang, J., and Liang, S., Measurement and modeling concrete creep considering relative humidity effect, Mechanics of Time-Dependent Materials, 2020, 24: 161-177.（高被引）

36.Liang, S., Wei, Y.*, Biaxial creep of high-strength concrete at early ages assessed from restrained ring test, Cement and Concrete Composites, 104, 2019.

37.Wei, Y.*, Kong, W., Wan, Ch., and Wang, Y., The colorimetry method in assessing fire-damaged concrete, Journal of Advanced Concrete Technology, 2019, 17(6):282-294.

38.Huang, W., Guo, W., Wei, Y.*, Thermal effect on rheological properties of epoxy asphalt mixture and stress prediction for bridge deck paving, ASCE’s Journal of Materials in Civil Engineering, 2019, 31(10): 0419222.

39.Wei, Y.*, Liang, S., and Huang, J., Concrete creep modeling: Application to slabs on ground, ASCE’s Journal of Engineering Mechanics, 2019, 145(10): 04019078.

40.Wei, Y.*, Wu, Z., Yao, X., and Gao, X., Quantifying effect of later curing on pores of paste subject to early-age freeze-thaw cycles by different techniques, ASCE’s Journal of Materials in Civil Engineering, 2019, 31(8): 04019153.

41.Liang, S., Wei, Y.*, Methodology of obtaining intrinsic creep property of concrete by flexural deflection test, Cement and Concrete Composites, 2019, 97: 288-299.

42.Wei, Y.*, Gao, X., Wang, F., and Zhong, Y., Nonlinear strain distribution in a field-instrumented concrete pavement slab in response to environmental effects, Road Materials and Pavement Design, 2019, 20(2): 367-380.

43.Wei, Y.*, Wu, Z., Huang, J., and Liang, S., Comparison of compressive, tensile, and flexural creep of early-age concretes under sealed and drying conditions, Journal of Materials in Civil Engineering, 2018, 30(11): 04018289-1-13.

44.Liang, S., Wei, Y.*, Wu, Z., and Hansen, W., Performance evaluation of concrete pavement slab considering creep effect by finite element analysis, Transportation Research Record: Journal of the Transportation Research Board, 2018, 2672 (27): 65-77.

45.Gao, X., Wei, Y.*, Huang, W., Critical aspects of scanning probe microscope mapping when applied to cement pastes, Advances in Cement Research, 2018, 30(7): 293-304.

46.Liang, S., Wei, Y.*, Modeling of creep effect on moisture warping and stress developments in concrete pavement slabs, International Journal of Pavement Engineering, 2018, 19(5): 425-438.

47.Wei, Y.*, Gao, X., and Liang, S., A combined SPM/NI/EDS method to quantify properties of inner and outer C-S-H in OPC and slag-blended cement pastes, Cement and Concrete Composites, 2018, (85), 56-66.

48.Wei, Y.*, Guo, W., Liang, S., Chloride ingress in internally cured concrete under complex solution, Journal of Materials in Civil Engineering, 2018, 30 (4): 04018037-1-10.