基本情况
姓名:马柳昊
出生年月:1990年10月
职称:教授
导师类别:博士生导师、硕士生导师
主要研究方向:先进光学测试诊断方法、气体激光传感器与雷达设计、软件开发
工作单位:汽车工程学院
邮箱:liuhaoma@whut.edu.cn,lhma@link.cuhk.edu.hk
教育背景
2015.08 –2019.07 香港中文大学,机械与自动化工程,哲学博士
2012.09 –2015.06 华中科技大学,热能工程,工学硕士
2008.09 –2012.06 华中科技大学,热能与动力工程,工学学士
工作经历
2026.04–至今 武汉理工大学,特岗教授
2024.09–2026.04 武汉理工大学,副教授
2022.08–2024.08 武汉理工大学,特任副研究员
2020.12–2022.07 武汉理工大学,讲师
2019.09–2020.12 香港中文大学,博士后研究员
奖励情况
2025年,武汉理工大学青年拔尖人才
2023年,湖北省高层次创新人才项目
2022年,湖北省楚天学者-楚天学子项目
2022年,中国轻工业联合会科技进步一等奖
2021年,湖北省武汉英才-优秀青年人才项目
学术兼职情况(如有)
《Proceedings of the Combustion Institute》、《Combustion and Flame》、《Measurement Science and Technology》、《Photonics Research》、《Energy》、《Optics Express》、《Applied Optics》、《Applied Physics B》等杂志审稿人
科研项目情况
[1] 2025-2028,外差相敏式波长调制色散光谱燃烧诊断方法研究,国家自然科学基金-面上项目,主持
[2] 2022-2024,基于跨谱带激光吸收诱导色散光谱技术的燃烧诊断方法研究,国家自然科学基金-青年基金,主持
[3] 2025-2028,融合迁移学习的氨进料工业窑炉炉内多理化量分布式监 测技术和系统开发,国家重点研发计划子课题,主持
[4] 2024-2026 国家重大科技基础设施项目任务,主持
[5] 2024-2026,铝棒加热炉氨燃料绿色低碳制造关键技术,粤佛基金重点项目课题,主持
[6] 2024-2027,佛山仙湖实验室重大项目课题,主持
[7] 2022-2023,佛山仙湖实验室重大项目课题,主持
[8] 2021-2024,若干企事业单位委托项目,主持
参与香港研究资助局优配研究基金,香港创新科技署创新及科技基金,国家重点研发计划"政府间国际科技创新合作"重点专项,国家自然科学基金优秀青年科学基金项目(港澳)及面上项目等。
代表性学术成果
SCI Journals
[1] Q. Li, L. Ma*, J. Li, Y. Wang*. Quantitative measurements of NO oxidation rate using wavelength modulation spectroscopy and implications to NO sampling in ammonia flames. Sensors and Actuators B: Chemical,448, 138972 (2026).
[2] B. Sun, C. Yu, Z. Yu, T. Wan, L. Ma, Y. Wang*. Efficient characterization of the two-dimensional and buoyancy effects in counterflow diffusion flames. Fuel 405, 136495 (2026).
[3] T. Wan, Y. Liu*, W. Shao, S. Zhang, Y. Huang, L. Ma*, Characterization of the non-uniform thermochemical structure of laminar premixed stagnation flame using mid-infrared laser absorption tomography, Case Studies in Thermal Engineering, 78, 107707 (2026).
[4] B. Cui, L. Ma*, B. Sun, Q. Li, Y. Wang*. Mid-infrared absorption spectroscopy for in-situ and spatially-resolved measurements of nitric oxide in premixed ammonia-methane co-fired flames. Optics Express, 33 (2), 3262-3280 (2025).
[5] Q. Li, L. Ma, J. Zhou, J. Li, F. Yan, J. Du, Y. Wang*. A comprehensive parametric study on NO and N2O formation in ammonia-methane cofired premixed flames: Spatially resolved measurements and kinetic analysis. Combustion and Flame, 272, 113851 (2025).
[6] W. Hu, L. Ma*, J. Zhou, Y. Wang*.Single filtered photodetector-based H2O emission thermometry for ammonia flames: a cost-effective optical sensing approach. Measurement Science and Technology, (2025).
[7] Y. Yan, L. Ma*, Q. Li, Y. Wang*. Simultaneous measurement of NO and NH3 in ultra-high humidity flue gases from ammonia combustion using mid-infrared laser-absorption spectroscopy. Energy & Fuels, 39,14921-14934 (2025).
[8] Q. Li, J. Li, B. Sun, L. Ma*, Y. Wang*. A comparative study on the effects of temperature on NO formation in ammonia/methane flames. Chemical Engineering Journal, 520, 166282, (2025).
[9] W. Wang, P. Fu, Z. Song, Z. Wang, N. Zhu, L. Ma, X Chao. Compact mid-infrared laser sensor for temperature and CO concentration measurement using heterodyne phase-sensitive dispersion spectroscopy, Measurement, 244, 116084 (2025).
[10] J. Zhou, L. Xu*, J. Du, L. Ma, Y. Wang*. Infrared imaging for two-dimensional soot and temperature measurements in laminar premixed and non-premixed flames. Journal of the Energy Institute, 120, 102111 (2025).
[11] T. Jiao, S. Kou, L. Ma, K-P Cheong, W. Ren, Extending sensing range by physics constraints in multiband-multiline absorption spectroscopy for flame measurement, Sensors, 25 (7), 2317 (2025).
[12] L. Ma, C. Zhou, Z. Wang, W. Ren, Y. Wang*. Calibration-free heterodyne phase-sensitive dispersion spectroscopy: Quantitative gas sensing and recovery of absorption spectra. Optics Express, 32, 37492-37515 (2024).
[13] Q. Li, L. Fu, Z. Zhang, L. Ma, H. Ning*, Y. Wang*, H.Y. Zhao. A theoretical study on the isomerization and decomposition reaction kinetics of small unsaturated methyl esters: Methyl acrylate, methyl butenoate and methyl crotonate radicals. Combustion and Flame, 265, 113519 (2024).
[14] H. Sun, D. Wen, K-P. Cheong, L. Ma, K. Ni, W. Ren*. Cavity-enhanced dual-comb spectroscopy for sensitive OH detection in a laminar premixed flame. Proceedings of the Combustion Institute, 40, 105662, (2024).
[15] W. Zhang, Z. Zhang, X. Han, C. Yuan, Y. Liu*, L. Ma, W. Ren. On the determination of the standing oblique detonation wave in an engine combustor using laser absorption spectroscopy of hydroxyl radical, Aerospace Science and Technology, 152, 109344, (2024).
[16] J. Zhou, Z. Yu*, L. Ma, X. Zhu, S. Jin, J. Du*, X. Cheng, S. Ke, G. Xie, Y. Cheng, Y. Wang. Pure ammonia-fueled roller kiln for the production of ceramic tiles: A first demonstration. Energy & Fuels, 38, 22593-22604, (2024) .
[17] Q. Li, F. Ji, W. Wang, L. Ma*, Y. Wang. A mid-infrared laser absorption sensor for calibration-free measurement of nitric oxide in laminar premixed methane/ammonia co-fired flames. Microwave and Optical Technology Letters, 66, e33815 (2024).
[18] S. Wang, M. Gu, S. Yin, Z. Zhou, L. Ma, F. Qi. In-situ Measurement of CO2 Column Density and Flame Temperature of Single Biomass Particle Combustion by Laser Absorption Spectroscopy. Chinese Journal of Chemical Physics, 37(6): 745-753 (2024).
[19] J. Zhou, Z. Yu*, L. Ma, X. Zhu, S. Jin, J. Du*, X. Cheng, S. Ke, G. Xie, Y. Cheng, Y. Wang. Pure ammonia-fueled roller kiln for the production of ceramic tiles: A first demonstration. Energy & Fuels 2024; 38, 22593-22604.
[20] L. Ma, W. Du, D. Wen, Y. Wang*. Infrared multi-spectral soot emission for robust and high-fidelity flame thermometry. Optics Letters, 48(4), 980-983, (2023).
[21] L. Ma*, W. Wang, C. Zhou, Y. Wang*. A laser absorption sensor for fuel slip monitoring in high-humidity flue gases from ammonia combustion. Measurement Science and Technology 34, 094005 (2023).
[22] L. Ma, W. Hu, W. Wang, Y. Wang*. Transfer learning-based multi-wavelength laser sensor for high fidelity and real-time monitoring of ambient temperature and humidity. Applied Optics 62, 5932-5945 (2023).
[23] G. Sheng, J. Han, L. Ma*, W. Wang, Y. Wang. Mid-infrared absorption tomography for in situ analysis of thermochemical structure in natural gas-fired cooker flame. Microwave and Optical Technology Letters 65, 1215-1222 (2023).
[24] W. Du, D. Wen, L. Ma, Y. Wang*. Development and validation of a hybrid constraint spectral thermometry for laminar sooting flames. Applied Optics 61, 8341-8353, (2022).
[25] L. Ma*, K-P Cheong*, K. Duan, W. Ren, "Hybrid constraint multi-line absorption spectroscopy for non-uniform thermochemical measurements in axisymmetric laminar and jet flames", Optics and lasers in Engineering, 154, 107014, (2022).
[26] J. Zhou, M. Zhou, L. Ma, Y. Wang*. Slight asymmetry induces significant distortion in soot volume fraction measurements in counterflow diffusion flames with diffuse back-illumination imaging, Optics Express, 30, 6671-6689, (2022).
[27] G. Sheng, L. Ma*, D. Wen, Y. Wang*. Simultaneous measurements of temperature, CO2 concentration and soot volume fraction in counterflow diffusion flames using a single mid-infrared laser, Applied Physics B: Lasers and Optics, 128, 62, (2022).
[28] D. Wen, L. Ma*, Y. Wang*, "Effects of thermochemical non-uniformity on line-of-sight laser absorption thermometry in counterflow diffusion flames", Journal of Quantitative Spectroscopy and Radiative Transfer, 277, 107990, (2022).
[29] L. Ma, K-P. Cheong*, M. Yang, C. Yuan, W. Ren*. On the quantification of boundary layer effects on flame temperature measurements using line-of-sight absorption spectroscopy. Combustion Science and Technology,194, 3259-3276 (2022).
[30] K. Xu, L. Ma, J. Chen, X. Zhao, Q. Wang, R. Kan, Z. Zheng*, W. Ren*. Dual-comb spectroscopy for laminar premixed flames with a free-running fiber laser. Combustion Science and Technology, 194, 2523-2538 (2022).
[31] M. Zhou, F. Yan, L. Ma*, P. Jiang, Y. Wang*, S. Chung, "Chemical speciation and soot measurements in laminar counterflow diffusion flames of ethylene and ammonia mixtures", Fuel, 308, 122003 (2022).
[32] W. Duan, F. Yan, H. Zhang, L. Ma*, D. Wen, W. Wang, G. Sheng, Y. Wang, Q. Wang*. "A laser-based multipass absorption sensor for sub-ppm detection of methane, acetylene and ammonia", Sensors, 22(2), 556, (2022).
[33] L. Ma*, K. Duan, K-P Cheong*, W. Ren, "Multispectral infrared absorption spectroscopy for quantitative temperature measurements in axisymmetric laminar sooting flames", Case Studies in Thermal Engineering,28, 101575 (2021).
[34] M. Raza, L. Ma*, S. Yao, L. Cheng, W. Ren*, "High-temperature dual-species (CO/NH3) detection using calibration-free scanned-wavelength-modulation spectroscopy at 2.3 μm ", Fuel, 305, 121591 (2021).
[35] L. Ma, K-P. Cheong, H. Ning, W. Ren*, "An improved study of the uniformity of laminar premixed flames using laser absorption spectroscopy and CFD simulation", Experimental Thermal and Fluid Science, 112 110013 (2020).
[36] L. Ma, Z. Wang, K-P. Cheong, H, Ning, and W. Ren*, "Mid-infrared heterodyne phase-sensitive dispersion spectroscopy in flame measurements", Proceedings of the Combustion Institute, 37(2), 1329−1336 (2019).
[37] L. Ma, H. Ning, J. Wu, K-P. Cheong, W. Ren*, "Characterization of temperature and soot volume fraction in the laminar premixed sooting flame: laser absorption/extinction measurement and 2D CFD simulation", Energy & Fuels, 32(12), 12962−12970 (2018).
[38] L. Ma, H. Ning, J. Wu, W. Ren*, "In situ flame temperature measurements using a mid-infrared two-line H2O laser-absorption thermometry", Combustion Science and Technology, 190(3), 392−407 (2018).
[39] L. Ma, Z. Wang, K-P. Cheong, H, Ning, and W. Ren*, "Temperature and H2O sensing in laminar premixed flames using mid-infrared heterodyne phase-sensitive dispersion spectroscopy", Applied Physics B: Lasers and Optics, 124:117 (2018).
[40] L. Ma, L.Y. Lau, and W. Ren*, "Non-uniform temperature and species concentration measurements in a laminar flame using multi-band infrared absorption spectroscopy", Applied Physics B: Lasers and Optics, 123:83 (2017).
中文期刊
[1] 周晨,郭双,马柳昊*. 激光色散光谱高温气体传感技术研究进展. 计测技术,45(4): 119-140 (2025).
[2] 郭双,周晨,余为,马柳昊,杜建国,王宇,基于波长调制的外差相敏色散光谱技术. 光学学报,已录用 (2025).
[3] 李琦,王昊,马柳昊*,周晨,严永胜,杜建国,王宇,基于波长调制光谱技术的高湿烟气残余氧定量测量,光电工程,025; 52(9): 250236 (2025).
[4] 万涛,陆盛曜,马柳昊*,孙博闻,黄奕涛,王宇. 基于视线效应修正的中红外激光吸收光谱对冲扩散火焰温度测量方法. 光学精密工程,33(18): 2833-2843 (2025).
[5] 王昊, 马柳昊*, 杜建国, 周晨, 王玮, 王伟, 王宇. 基于频分复用激光吸收光谱技术的高湿烟气中痕量甲烷-氨双元燃料逃逸测量. 化工进展,44 (4): 1913-1922 (2025) .
[6] 王玮,马柳昊*,杜建国,王昊,周晨,王宇. 基于波长调制光谱技术的氢浓度快速检测. 大气与环境光学学报,已录用.
[7] 吴小广,马柳昊*,严永胜,李青,王宇. 基于10.4 μm量子级联激光器及波长调制光谱技术的高温痕量氨检测. 量子电子学报,已录用.
[8] 陆盛曜,马柳昊*,张健鹏,李青,周吉伟,万涛,王宇. 中红外层析吸收光谱技术应用于甲烷掺氨层流预混火焰温度测量. 光学精密工程(封面论文). 32(18): 2733-2743 (2024).
[9] 周晨,马柳昊*,王宇. 基于外差相敏色散光谱技术的宽动态范围甲烷气体检测. 中国光学, 17(4): 789-800,(2024).
[10] 刘宁博,赵逸佳,陆盛曜,马柳昊*. 热化学参数非均匀分布对双色激光吸收光谱测量碳烟火焰温度的影响. 光学精密工程 ,31(19):2799-2808 (2023).
[11] 任伟*,马柳昊,顾明明. 面向燃烧在线监测的激光传感技术进展. 工程热物理学报,已录用.
[12] 纪飞宇,李青,马柳昊,杜建国*,王宇. 氨气/甲烷层流预混火焰NO生成特性研究. 工程热物理学报,46(5): 1719-1727(2025).
[13] 李锦涛,李青,纪飞宇,马柳昊,王宇*. 水蒸气添加对氨/甲烷火焰中NO生成特性的影响研究. 燃烧科学与技术,31(04): 466-478(2025).
