www.bifa88.com-88bifa必发官网-bifa88

n 2006-2010 清华大学，航天航空学院（本科）

n 2010-2013 中国科学院大学，工程热物理研究所（硕士）

n 2013-2016 美国弗吉尼亚理工大学（Virginia Tech），航天航海工程系（博士）

n 2017-2018 美国明尼苏达大学双城分校（University of Minnesota, Twin City），SAFL流体实验室 （博士后）

n 2018-2023 www.bifa88.com-88bifa必发官网-bifa88，机械与车辆学院，发动机研究所（预聘副教授）

n 2024- www.bifa88.com-88bifa必发官网-bifa88，机械与车辆学院，发动机研究所（长聘副教授）

n 复杂流动/燃烧系统的非介入性测量（实验测试）

n 三维光学诊断计算成像算法开发（算法编程）

n 流体动力学和化学反应动力学机理研究（理论分析）

n 科技创新计划原创基础前沿交叉学科项目，www.bifa88.com-88bifa必发官网-bifa88，2023年1月-2024年12月；

n JKW XXX项目，ZB发展部，2022/09-2023/08；

n 直喷式汽油机点火过程的三维跨界面层析诊断技术优化，北京市自然科学基金面上项目, 2022/01-2024/12；

n 基于跨缸壁三维层析重构的内燃机点火过程试验研究，内燃机国家重点实验室开放课题, 2021/06-2023/06；

n 缸内喷雾结构的跨界面高精度三维层析测量方法研究，国家自然科学基金青年项目，2020/01-2022/12。

1) Chen H, Ling C, Wu Y, et al. Cross-interface computed tomography applied in flame propagation detection of an optical engine[J]. Combustion and Flame, 2024, 261:113288.

2) Hao L, Liu T, Kong D, et al. Flow pattern regime and unsteady characteristics of ventilated cavitating flow around the axisymmetric bodies with different headforms[J]. Physics of Fluids, 2023, 124103.

3) Chen H, Shi Z, Wu Y, et al. Investigation of the injection pressure impact on non-monotonic two-stage ignition delay of diesel engines under cold-start[J]. Applied Thermal Engineering, 2023, 235:121408.

4) Gong B, Ling C and Wu Y. Development of a direct‑mapping tomography method to solve confined space problems with enhanced calculation efficiency[J]. Applied Physics B, 2023, 129:128.

5) Gao Y, Ling C, Wu Y, et al. Volumetric flame reconstructions in an optical engine cylinder involving refraction and blockage[J]. Measurement Science and Technology, 2023, 34(7):074007. 01

6) Ling C, Chen H, Wu Y, et al. 3D Measurements of a Two‑Phase Flow Inside an Optical Cylinder Based on Full‑Field Cross‑Interface Computed Tomography[J]. Flow, Turbulence and Combustion, 2023, 111:333-353.

7) Hao L, Kong D, Wu Y, et al. Transition and gas leakage mechanisms of ventilated cavities around a conical axisymmetric body[J]. Physics Review Fluids, 2022, 7: 123901.

8) Gao Y, Ling C, Wu Y, et al. A sensor arrangement optimization method for volumetric tomography: effective voxel correction maximization (EVCM)[J]. Applied Physics B: Lasers and Optics, 2022, 128(9): 173.

9) Wu H, Gao Y, Wu Y, et al. Computed tomography in resolving flame topology with internal optical blockage involved[J]. Applied Optics, 2022, 61(17): 5161-5171.

10) Chen H, Shi Z, Liu F, et al. Non-monotonic change of ignition delay with injection pressure under low ambient temperature for the diesel spray combustion[J]. Energy, 2022(243): 123017.

11) Chen H, Ling C, Wu Y, et al. Correlation-based view registration for 3D tomography[J]. Applied Optics, 2022, 61(10): 2620-2628.

12) Ling C, Chen H, Gao Y, et al. Algorithm optimization of cross-interfaces computed tomography into full field[J]. Applied Optics, 2021, 60(15): 4469-4476.

13) Niu Q, Sun B, Wu Y, et al. Effects of intake valve opening duration on performance optimization of an Atkinson cycle engine under part load[J]. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Auto mobile Engineering, 2021, 235(14): 3557-3570.

14) Ling C, Chen H and Wu Y. Development and validation of a reconstruction approach for three-dimensional confined-space tomography problems[J]. Applied optics, 2020, 59(34):10786-10800.

15) Liu N, Lei Q, Wu Y, et al. 3D tomography reconstruction improved by integrating view registration[J]. Applied optics, 2019, 58(10): 2596-2604.

16) Qin S, Wu Y, Wu D, et al. Experimental investigation of ventilated partial cavitation[J]. International Journal of Multiphase Flow, 2019, 113: 153-164.

17) Wu Y, Liu Y, Shao S, et al. On the internal flow of a ventilated supercavity[J]. Journal of Fluid Mechanics, 2019, 862: 1135-1165.

18) Dasari T, Wu Y, Liu Y, et al. Near-wake behaviour of a utility-scale wind turbine[J]. Journal of Fluid Mechanics, 2019, 859: 204-246.

19) Shao S, Wu Y, Haynes J, et al. Investigation into the behaviors of ventilated supercavities in unsteady flow[J]. Physics of Fluids, 2018, 30(5):052102.

20) Liu N, Wu Y, Ma L. Quantification of tomographic PIV uncertainty using controlled experimental measurements[J]. Applied optics, 2018, 57(3): 420-427.

21) Wu Y, Xu W, Ma L. Kilohertz VLIF (volumetric laser induced fluorescence) measurements in a seeded free gas-phase jet in the transitionally turbulent flow regime[J]. Optics and Lasers in Engineering, 2018, 102(MAR.):52-58.

22) Ma L, Lei Q, Ikeda J, et al. Single-shot 3D flame diagnostic based on volumetric laser induced fluorescence (VLIF)[J]. Proceedings of the Combustion Institute, 2017, 36(3): 4575-4583.

23) Ma L, Wu Y, Xu W, et al. Comparison of 2D and 3D flame topography measured by planar laser-induced fluorescence and tomographic chemiluminescence[J]. Applied optics, 2016, 55(20): 5310-5315.

24) Lei Q, Wu Y, Xu W, et al. Development and validation of a reconstruction algorithm for three-dimensional nonlinear tomography problems[J]. Optics express, 2016, 24(14): 15912-15926.

25) Ma L, Lei Q, Wu Y, et al. From ignition to stable combustion in a cavity flame holder studied via 3D tomographic chemiluminescence at 20 kHz[J]. Combustion and Flame, 2016, 165: 1-10.

26) Ma L, Wu Y, Lei Q, et al. 3D flame topography and curvature measurements at 5 kHz on a premixed turbulent Bunsen flame[J]. Combustion and Flame, 2016, 166: 66-75.

27) Wu Y, Xu W, Lei Q, et al. Single-shot volumetric laser induced fluorescence (VLIF) measurements in turbulent flows seeded with iodine[J]. Optics express, 2015, 23(26): 33408-33418.

28) Ma L, Lei Q, Wu Y, et al. 3D measurements of ignition processes at 20 kHz in a supersonic combustor[J]. Applied Physics B, 2015, 119(2): 313-318.

29) Xu W, Wickersham A J, Wu Y, et al. 3D flame topography obtained by tomographic chemiluminescence with direct comparison to planar Mie scattering measurements[J]. Applied optics, 2015, 54(9): 2174-2182.

30) Kang M W, Wu Y, Ma L. Fiber-based endoscopes for 3D combustion measurements: view registration and spatial resolution[J]. Combustion and flame, 2014, 161(12): 3063-3072.

31) Lei Q, Wu Y, Xiao H, et al. Analysis of four-dimensional Mie imaging using fiber-based endoscopes[J]. Applied optics, 2014, 53(28): 6389-6398.

32) Wu Y, Lei Q, Ma L. Experimental demonstration of 4D imaging in two-phase flows based on computed tomography at 5 kHz[J]. Applied optics, 2014, 53(24): 5547-5553.

1) 高宇, 陈海岩, 伍岳. 基于三维层析技术的光学柴油发动机机内火焰重构[C]// 工程热物理学会燃烧学年会, 合肥, 安徽, 中国, 2023.

2) 凌晨, 龚步高, 伍岳. 直接映射跨界面层析算法设计[C]// 工程热物理学会燃烧学年会, 合肥, 安徽, 中国, 2023.

3) 凌晨，陈海岩，伍岳. 基于受限空间三维层析方法的喷雾瞬态结构测量研究[C]//工程热物理学会燃烧学年会, 上海, 中国, 2022.

4) 伍岳. 受限空间计算层析技术优化方法研究[C]//第七届全国青年燃烧学术会议, 厦门, 中国, 2022.

5) 吴海丰，高宇，伍岳. 光路遮挡下的三维层析诊断精度最优化方法研究[C]//工程热物理学会燃烧学年会, 大连, 中国, 2021.

6) 高宇, 凌晨, 伍岳, 陈海岩, 吴海丰. 一种基于有效体素修正的层析相机排布优化方法[C]//工程热物理学会燃烧学年会, 大连, 中国, 2021

7) 伍岳. 跨界面计算层析技术的实现与优化[C]//第六届全国青年燃烧学术会议, 杭州, 中国, 2021.

8) 高宇, 龚步高, 伍岳. 用于内燃机燃烧诊断的三维层析相机优化布置方法[C]//第二届世界内燃机大会, 济南, 中国, 2021.

9) 陈海岩, 吴海丰, 伍岳. 用于内燃机缸内诊断的三维层析高精度标定方法[C]//第二届世界内燃机大会, 济南, 中国, 2021.

10) 凌晨, 陈海岩, 伍岳. 三维跨缸壁层析成像重建方法的发展和验证[C]//第二届世界内燃机大会, 济南, 中国, 2021.

11) Chen H, Liu F, Li Y, et al. Experimental studies on the effects of injection pressure on the ignition and combustion characteristics of diesel spray under cold-start conditions[C]//ILASS-Asia 2020, Zhenjiang, China, 2020.

12) 凌晨, 伍岳. 三维层析诊断跨界面成像修正方法研究[C]//工程热物理学会燃烧学年会, 天津, 中国, 2019.

13) Hong, J, Dasari T, Wu Y, et al. Velocity field and coherent structures in the near wake of a utility-scale wind turbine[C]. In: Aps Meeting, Boston, Massachusetts, USA, 2019.

n 2022 北京市高等教育教学成果奖二等奖

n 2021 www.bifa88.com-88bifa必发官网-bifa88优秀教育教学成果一等奖

n 2020 《实验流体力学》2020年度优秀论文

n 2017 第36届国际燃烧学会议Distinguished Paper Award

n 中国光学工程师学会光谱专委会委员

n 国际期刊论文审稿：Proceedings of combustion institute, Combustion and flame, Optics Letters等

n 全国工程热物理年会燃烧分会（2020年，厦门）分会主持

n 第六届全国青年燃烧学术会议（2021年，杭州）特邀报告

n 第二届光谱测量技术及应用大会暨第六届燃烧诊断研讨会（2021年，上海） 特邀报告