2015.12~2016.06， 釜山国立大学(韩国)，动力工程及工程热物理专业，博士交换生。
2014.09~2019.03， 上海交通大学，动力工程及工程热物理专业，博士。
2012.09~2014.06， 华中科技大学 ，动力工程专业，硕士。
2008.09~2012.06， 华中科技大学，能源与动力工程专业，本科。

2023.05~至今，上海交通大学，叶轮机械研究所，副教授，博导
2021.08~2023.04，釜山国立大学（Pusan National University(韩国)), 机械工程学院，Eco-friendly Smart Ship Parts Technology Innovation Center，研究教授（Research Professor）
2020.09~2021.07，釜山国立大学（Pusan National University(韩国)), 机械工程学院，Eco-friendly Smart Ship Parts Technology Innovation Center，副研究员
2019.09~2020.08，釜山国立大学（Pusan National University(韩国)), 机械工程学院，Rolls-Royce Thermal Research Center，副研究员
2019.04~2019.08，马格德堡大学（Otto von Guericke University Magdeburg (德国)），博士后研究员

一、先进磷光测量方法与技术
1）热物理参数磷光响应原理；
2）高温环境下基于磷光的先进非接触测量方法与技术，包括温度场，压力场，速度场，应力/应变场等；
3）多参数场测量技术：流场温度-速度同步测量技术；壁面温度-压力同步测量技术；壁面温度-应变同步测量技术 ；

二、工程及应用
1）智能传感器（柔性光学皮肤）；
2）燃气轮机/航空发动机热物理参数测试技术，燃料电池的热传感和热管理等；
3）AI辅助的高频高分辨率数据重构技术。

 欢迎对发光材料、热动、机械、光学、图像处理等相关领域感兴趣的同学邮件咨询。

担任Advanced Materials，Applied Physics Letters，Optics and Lasers in Engineering，Measurement Science and Technology，Materials Research Express，Journal of Optics，Journal of Visualization，Engineering Research Express，Methods and Applications in Fluorescence，Review of Scientific Instruments，Sensors，Nanotechnology，Materials 等20余SCI期刊审稿人。

第19届国际流动显示（ISFV）会议组委会委员。
第6届国际流动-结构-噪声作用与控制（FSSIC）会议组委会委员。

1. 国家海外高层次青年人才计划项目，2024-2026，主持。
2.白玉兰人才浦江项目（上海市），基于磷光的航空发动机叶片表面温度及热应变测量方法研究，2023-2025，30万，主持。
3.上海交通大学启动基金，2023-2026，80万，主持
4. 韩国国家研究基金会（NRF），高温环境下基于磷光的温度/速度/压力/应力非接触测量研究，人民币约200万，2019-2023，NRF. 2019H1D3A1A0107033，主持。
5. 韩国国家研究基金会（NRF），环保智能船舶零部件技术创新RLRC项目，人民币约1 亿，2020-2027，NRF. 2020R1A5A8018822，参与。

已发表：

[34] Cai, T., Luan, D., Wang, P., He, C., Liu, Y., & Peng, D. (2025). Flow dynamics and oscillation mechanisms in T-junction mixing flows using time-resolved particle image velocimetry and spectral proper orthogonal decomposition analysis. Physics of Fluids, 37(5). (Editor's Picks)

[33] Cai, T., Luan, D., Fu, R., Liu, Y., Peng, D., Cai, W., & Liu, H. (2025). Simultaneous temperature and velocity measurements based on novel fluid density-matched phosphorescent microspheres. Experiments in Fluids, 66(2), 36.

[32] Im, Y.*, Cai, T.*, Lee, S., Kim, P., & Yeom, E. (2025). Whole field measurement of temperature and strain using phosphorescence imaging with inpainting technique. International Journal of Heat and Mass Transfer, 239, 126595.

[31]Roadmap on Industrial Imaging Techniques (2025). Measurement of Science and Technology: Section 9: Phosphor thermometry. 36 013001

[30] Cai, T., Fu, R., Luan, D., Liu, Y., & Peng, D. (2024). Three-dimensional surface temperature measurement using lifetime-based phosphor thermometry. Measurement Science and Technology, 35(10), 105022.

[29] Jung, J., Kim, M., Cai, T., Liu, Y., & Kim, K. C. (2023). Data recovery of 2D lifetime-based phosphor thermometry using deep neural networks. Measurement Science and Technology, 34(7), 075201.  
[28] Mohammadshahi, S., Samsam-Khayani, H., Chen, B., Cai, T., & Kim, K. C. (2023). Visualization of two-dimensional temperature field on a plate with normal impingement of a supersonic jet. Journal of Visualization, 1-10. 
[27] Cai, T., Chen, B., Han, J., Kim, M., Yeom, E., & Kim, K. C. (2022). Effect of excitation duration on phosphorescence decay and analysis of its mechanisms. Journal of Luminescence, 252, 119423.  
[26] Cai T, Han J, Kim M, et al. Adaptive window technique for lifetime-based temperature and velocity simultaneous measurement using thermographic particle tracking velocimetry with a single camera[J]. Experiments in Fluids, 2022, 63(10): 1-11.  
[25] Cai T, Jung J, Li D, et al. Simultaneous Sensing of Oxygen Concentration and Temperature Utilizing Rise and Decay of the Phosphorescence of Y2O3: Eu3+ in High-temperature Environments[J]. Sensors and Actuators B: Chemical, 2022: 132394.  
[24] Cai T, Li D, Jung J, et al. Two-dimensional visualization of oxygen concentration field at high-temperature environment using phosphor Y2O3: Eu3+[J]. Sensors and Actuators B: Chemical, 2022, 364: 131884.  
[23] Cai T, Han J, Kim M, et al. Two-dimensional lifetime-based kHz surface temperature measurement technique using phosphor thermometry[J]. Applied Physics Letters, 2021, 119(24): 244101. 
[22] Cai T, Yan Y Z, Jung J, et al. Phosphorescence-based temperature and tactile multi-functional flexible sensing skin[J]. Sensors and Actuators A: Physical, 2021, 332: 113205.  
[21] Park Y, Cai T, Kim K. A Study on Non-contact Surface Temperature Field Measurement of a Body Immerged in Water Using Thermographic Phosphor Thermometry[J]. Journal of the Korean Society of Visualization, 2020, 18(3): 61-68.
[20] Cai T, Park Y, Mohammadshahi S, et al. Rise time-based phosphor thermometry using Mg4FGeO6: Mn4+[J]. Measurement Science and Technology, 2020, 32(1): 015201.  
[19] Mohammad S, Samsam H, Cai T, et al. Experimental and numerical study on flow characteristics and heat transfer of an oscillating jet in a channel[J]. International Journal of Heat and Fluid Flow, 2020, 86: 108701.  
[18] Cai T, Deng Z, Park Y, et al. Acquisition of kHz-frequency two-dimensional surface temperature field using phosphor thermometry and proper orthogonal decomposition assisted long short-term memory neural networks[J]. International Journal of Heat and Mass Transfer, 2021, 165: 120662.  
[17] Cai T, Yan Y,et al. Phosphorescence-Based Flexible and Transparent Optical Temperature-Sensing Skin Capable of Extreme Environments[J]. ACS Applied Polymer Materials, 2021, 3(5): 2461-2469.  
[16] Mohammad S, Samsam-Khayani H, Cai T, et al. Experimental study on flow characteristics and heat transfer of an oscillating jet in a cross flow[J]. International Journal of Heat and Mass Transfer, 2021, 173: 121208.  
[15] Cai T, Lee T, et al. Simultaneous measurement of 2D temperature and strain fields based on thermographic phosphor and digital image correlation[J]. Measurement Science and Technology, 2021. 
[14] Cai T, Khodsiani M, Hallak B, et al. Phosphor thermometry at the surface of single reacting large-diameter spherical coke particles to characterise combustion for packed bed furnaces[J]. Proceedings of the Combustion Institute, 2021, 38(3): 4225-4232. 
[13] 蔡涛、赵晓峰、刘应征、彭迪. 基于磷光光学特性的热障涂层热力参数测量技术[J]. 中国材料进展, 2020, v.39;No.466(10):26-37 (受邀综述)
[12] Guo S†, Cai T†, et al. Generalization of the quantitative stress-intensity relationship of mechanoluminescent sensor SrAl2O4: Eu2+, Dy3+ in elastic domain[J]. Measurement Science and Technology, 2019.  
[11] Li Y†, Cai T†, et al. Effect of oxygen partial pressure on the phosphorescence of different lanthanide ion (Ln3+)-doped yttria-stabilised zirconia[J]. Sensors and Actuators B: Chemical, 2020, 308: 127666.  
[10] Cai T, Li Y, Guo S, et al. Pressure effect on phosphor thermometry using Mg4FGeO6: Mn[J]. Measurement Science and Technology, 2019, 30(2): 027001.  
[9] Cai T, Guo S, Li Y, et al. Ultra-sensitive mechanoluminescent ceramic sensor based on air-plasma-sprayed SrAl2O4: Eu2+, Dy3+ coating[J]. Sensors and Actuators A: Physical, 2020, 315: 112246.  
[8] Peng D, Zhong Z, Cai T, et al. Integration of pressure-sensitive paint with persistent phosphor: A light-charged pressure-sensing system[J]. Review of Scientific Instruments, 2018, 89(8): 085003.  
[7] Cai T, Guo S, Li Y, et al. Quantitative stress measurement of elastic deformation using mechanoluminescent sensor: An intensity ratio model[J]. Review of Scientific Instruments, 2018, 89(4).  
[6] Cai T, Peng D, Yavuzkurt S, et al. Unsteady 2-D film-cooling effectiveness behind a single row of holes at different blowing ratios: Measurements using fast-response pressure-sensitive paint[J]. International Journal of Heat and Mass Transfer, 2018, 120: 1325-1340.  
[5] Peng D, Yang L, Cai T, et al. Phosphor-Doped Thermal Barrier Coatings Deposited by Air Plasma Spray for In-Depth Temperature Sensing[J]. Sensors, 2016, 16(10): 1490.  
[4] Cai T, Peng D, Liu Y Z, et al. A novel lifetime-based phosphor thermography using three-gate scheme and a low frame-rate camera[J]. Experimental Thermal and Fluid Science, 2017, 80: 53-60.  
[3] Cai T, Kim D, Kim M, et al. Effect of surface moisture on chemically bonded phosphor for thermographic phosphor thermometry[J]. Measurement Science and Technology, 2016, 27(9): 097003.  
[2] Cai T, Dong K, Kim M, et al. Two-dimensional thermographic phosphor thermometry in a cryogenic environment[J]. Measurement Science and Technology, 2016, 28(1).  
[1] Cai T, Peng D, Liu Y Z, et al. A correction method of thermal radiation errors for high-temperature measurement using thermographic phosphors[J]. Journal of Visualization, 2016, 19(3): 383-392.  

会议文章：
[1] Cai T†, Zhang WJ, Kim M, et al. Fabrication of Micro-size Encapsulated Phosphor Particles and Its Application of Temperature-velocity Measurement in Water [C]. KSME Annual Meeting2022, International Sessio, Jeju, Korea, 2022. (邀请报告)
[2] Cai T†, Han J, Kim KC, et al. Adaptive Window Technique For Lifetime-Based Temperature And Velocity Simultaneous Measurement Using Thermographic Particle Tracking Velocimetry With A Single Camera. The 13th Pacific Symposium on Flow Visualization and Image Processing, Shinjuku, Japan, 2022.
[3] Cai T†, Han J, Kim KC, et al. Adaptive Window Technique For Lifetime-Based Temperature And Velocity Simultaneous Measurement Using Thermographic Particle Tracking Velocimetry With A Single Camera. 2nd International Conference on Phosphor Thermometry, Magdeburg, Germany, 2022.
[4] Cai T†, Kim M, Chung W, et al. Development of phosphorescence-based in-situ temperature and strain measurement technology for SOFC cell monitoring [C]. 6th Asian SOFC Symposium and Exhibition, Jeju, Korea, 2021.
[5] Khodsiani M., Abram C, Cai T et al. Temperature measurements on the ash layer surface of reacting large-diameter coke particles [C]. 30. Deutscher Flammentag. Hannover-Garbsen, Germany, 2021
[6] Cai T†, Lee, T, Kim K, et al. Simultaneous Strain and Temperature Field Measurement Technique based on Digital Image Correlation and Thermographic Phosphor Thermometry [C]. 25th International Conference of Theoretical Applied and Experimental Mechanics, Milano, Italy, 2021.
[7] Cai T, Khodsiani M, Hallak B, et al. Phosphor thermometry at the surface of single reacting large-diameter spherical coke particles to characterise combustion for packed bed furnaces[C]. 38th International Symposium on Combustion, Adelaide, Australia, 2021
[8] Cai T†, Yan Y†, Kim K, et al. Phosphorescence-based Flexible Optical Temperature Sensing Skin: Capable of Extreme Environments [C].2nd International Conference on Phosphor Thermometry, Magdeburg, Germany, 2020.
[9] Cai T, Peng D, Yang L X, et al. Effect of oxygen on phosphorescence for different lanthanide ions Ln3+ doped yttria-stabilized zirconia [C].1st International Conference on Phosphor Thermometry, Glasgow, UK,2018.
[10] Li Y Z, Cai T, Peng D, et al. Development of a dual-component phosphor system for simultaneous pressure and temperature measurements [C].1st International Conference on Phosphor Thermometry, Glasgow, UK,2018.
[11] Cai T, Kim D, Kim M, et al. Assessment of Various Lifetime Based Post-processing Methods on Thermographic Phosphor Thermometry[C]. KSV, 2016, 04: 46-50. (Best Paper Award)

[1] 发明专利: 一种温度压力联合测量技术及测量方法: 中国, ZL201710706867.2
[2] 发明专利: 一种叶轮装置: 中国, CN103115021B
[3] 发明专利: Temperature sensing film and its measurement system: 韩国, KR2021/003322
[4] 发明专利: Temperature-sensitive film and measurement system using thereof:美国, P20200125US-02
[5] 发明专利: Method for manufacturing temperature and stress-sensitive film:韩国, KR2021/005007