马欲飞

基本信息 English Version 科学/教学研究 学生培养 论文著作(Publication) 新建主栏目 基本信息 名称 马欲飞，男，教授(破格)，国家优秀青年科学基金获得者、黑龙江省首批优青、哈尔滨工业大学青年拔尖人才计划入选者，哈尔滨工业大学青年科学家工作室学术带头人，2021年、2022年爱思唯尔中国高被引学者。长期从事激光传感、激光光谱及固体激光技术研究。担任Elsevier光声领域旗舰期刊《Photoacoustics》领域主编、美国光学学会国际知名期刊《Optics Express》副主编，同时还担任中国激光杂志社出版的著名期刊《Chinese Optics Letters》、SPIE 《Optical Engineering》等在内的8本SCI检索国际学术期刊领域主编/副主编/编辑，担任中国光学工程学会光谱技术及应用专委会副主任，担任多个知名学术期刊青年编委，担任国家自然科学基金会评专家。以第一作者/通讯作者在Science子刊《Ultrafast Science》、Light子刊《Light: Advanced Manufacturing》等期刊上发表论文近200篇，作为项目负责人主持国家部委、国家自然科学基金、黑龙江省优秀青年基金、华为公司技术开发等在内的多个项目。获“部级科技进步二等奖”、教育部“学术新人奖”、美国光学学会“Incubic/Milton Chang Travel Grant”等多项奖励。参与SPIE出版、1973年诺贝尔物理学奖获得者Leo Esaki教授和1985年诺贝尔物理学奖获得者Klaus von Klitzing教授任主编的书籍《The Wonder of Nanotechnology Quantum Optoelectronic: Devices and Applications》的编写，参与Springer出版的北约和平与安全系列丛书《NATO Science for Peace and Security Series B: Physics and Biophysics》的编写。 工作经历 标题 工作经历 起讫时间 职位/职称 教授 (破格，哈工大青年拔尖人才选聘计划) 工作单位 哈尔滨工业大学航天学院 简单介绍 标题 工作经历 起讫时间 职位/职称 博士生导师 (破格) 工作单位 哈尔滨工业大学航天学院 简单介绍 教育经历 标题 博士阶段 起讫时间 所学专业 Electrical and Computer Engineering 学习机构 美国Rice大学 学历 联合培养博士 简单介绍 主要任职 名称 1）担任国际著名期刊《Optics Express》副主编； 2）担任Elsevier出版的光声领域旗舰期刊《Photoacoustics》(SCI，IF=9.656，中科院1区)领域主编； 3）担任中国激光杂志社出版的著名期刊《Chinese Optics Letters》编委； 4）担任SPIE出版的《Optical Engineering》副主编； 5）担任Wiley出版的《Microwave and Optical Technology Letters》副主编； 6）担任《Frontiers in Physics》(SCI，IF=3.718) 副主编； 7）担任《Sensors》(SCI，IF=3.847) 编委； 8）担任《Applied Sciences》(SCI，IF=2.838) 编委； 9）担任IOP出版的《Journal of Optics》(SCI, IF=2.753)编辑顾问委员会； 10）担任Elsevier出版的《Photoacoustics》(SCI，IF=9.656，中科院1区)客座编辑； 11）担任《Sensors》(SCI，IF=3.847)客座主编； 12）担任《Frontiers in Physics》(SCI，IF=3.718) 客座主编； 13）担任《Applied Sciences》(SCI，IF=2.838)客座主编； 14）担任Wiley出版的《Microwave and Optical Technology Letters》客座主编； 15）担任《Journal of Spectroscopy》(SCI，IF=1.391)客座主编； 16）担任《Ultrafast Science》青年编委； 17）担任《哈尔滨工业大学学报》第14届青年编委； 18）担任《光学学报》专刊编委； 19）担任《光子学报》专刊编委； 20）担任《Laser Technology and its Applications》书籍主编； 21）担任中国光学工程学会光谱技术及应用专委会副主任； 22）担任教育部“CJ学者奖励计划”评审专家； 23）担任国家航天项目会评专家； 24）担任国家自然科学基金会评专家； 25）担任OSA Traveling Lecturer，美国光学学会旅行讲师； 26）担任美国光学学会哈尔滨工业大学学生分会学术顾问； 27) 中国激光杂志社青年编委； 28）黑龙江省光学学会理事； 29）中国光学学会激光光谱学专委会委员； 30）中国仪器仪表学会光机电分会常务委员 31）审稿人任职：担任《Science Advances》、《Optica》、《Applied Physics Letters》、《Optics Letters》、《Sensors and Actuators B》、《Optics Express》、《APL Photonics》、《Journal of the Optical Society of America B》、《Photoacoustics》、《Proceedings of the Combustion Institute》、《IEEE Transactions on Industrial Electronics》、《IEEE Transactions on Instrumentation & Measurement》、《Fuel》等近200个期刊的特邀审稿人。 荣誉奖励 名称 · 国家优秀青年科学基金获得者 · 《哈尔滨工业大学青年科学家工作室》学术带头人 · 部级科技进步二等奖 · 美国光学学会Incubic/Milton Chang Travel Grant奖励 · 美国光学学会Travel Grant for Frontier in Optics奖励 · 入选2022全球前2%顶尖科学家榜单 · 入选《全球顶尖科学家前10万榜单》 · 2023年度爱思唯尔中国高被引学者 · 2022年度爱思唯尔中国高被引学者 · 2021年度爱思唯尔中国高被引学者 · 黑龙江省首批优秀青年科学基金获得者 · 首届博士研究生国家奖学金 · 美国光学学会高级会员 · 科学中国人2017年度人物电子工程领域提名人 · 哈尔滨市青年后备人才 · 2023年度哈尔滨工业大学优秀硕士论文指导教师 · 2022年度哈尔滨工业大学优秀硕士论文指导教师 · 2021年度哈尔滨工业大学优秀硕士论文指导教师 · 2020年度哈尔滨工业大学优秀硕士论文指导教师 · 2019年度哈尔滨工业大学优秀硕士论文指导教师 · 2022年度哈尔滨工业大学百名优秀本科毕业设计指导教师 · 2020年度哈尔滨工业大学百名优秀本科毕业设计指导教师 · 2019年度哈尔滨工业大学百名优秀本科毕业设计指导教师 · 2018年度哈尔滨工业大学百名优秀本科毕业设计指导教师 · 2017年度哈尔滨工业大学百名优秀本科毕业设计指导教师 · 2017年度哈尔滨工业大学优秀专兼职工作者 · “第十届全国大学生光电设计竞赛”铜牌指导教师 · “第十一届全国大学生光电设计竞赛”优秀指导教师 · “第十届全国大学生光电设计竞赛东北区赛暨第六届东北地区大学生光电设计竞赛”优秀指导教师 · “第十一届全国大学生光电设计竞赛东北区赛暨第七届东北地区大学生光电设计竞赛”优秀指导教师 · 第八届中国国际“互联网%2B”大学生创新创业大赛省级银奖指导教师 · 第十五届“挑战杯”黑龙江省大学生课外学术科技作品二等奖指导教师 · 第七届“祖光杯”创意创新创业大赛银奖指导教师 · 哈尔滨工业大学青年拔尖人才选聘计划(正教授) · 哈尔滨工业大学青年拔尖人才选聘计划(副教授) · 教育部“学术新人奖” · 哈尔滨工业大学第十七届优秀博士学位论文 · 第一届美国光学学会哈尔滨工业大学学生分会 主席(创始人) · 《Ultrafast Science》期刊优秀传播奖 · 《光子学报》优秀审稿专家 · 《量子电子学报》优秀审稿专家 · 黑龙江省科技专家库专家 · 山西省科技奖励评审专家 · 四川省科技奖励评审专家 · 湖北省科技奖励评审专家 · 湖南省科技奖励评审专家 · 吉林省科技奖励评审专家 · 广西科技奖励评审专家 · 广东省科技奖励评审专家 · 吉林省教学奖励评审专家 · 美国光学学会哈尔滨工业大学Student Chapter 学术顾问 · 国家“建设高水平大学公派研究生项目奖学金” · 2018年度《中国光学十大进展》候选成果 · 2019年度《中国光学十大进展》候选成果 · 2022年度《Chinese Optics Letters》主编推荐奖 Brief Introduction 名称 Yufei Ma received his PhD degree in physical electronics from Harbin Institute of Technology, China, in 2013. From September 2010 to September 2011, he spent as a visiting scholar at Rice University, USA. Currently, he is a professor at Harbin Institute of Technology, China. He is the winner of National Outstanding Youth Science Fund. His research interests include optical sensors, trace gas detection, laser spectroscopy, solid-state laser and optoelectronics. He has published ~200 publications (including ~40 ESI hot/highly cited papers) and given more than 30 invited presentations at international conferences. He is the winner of 2021, 2022 Most Cited Researchers from Elsevier. He serves as Aera/Associate/Topical editor for SCI-indexed journals: Elsevier 《Photoacoustics》(IF=9.656), OSA 《Optics Express》(IF=3.8), SPIE 《Optical Engineering》(IF=1.3), Wiley 《Microwave and Optical Technology Letters》(IF=1.5), CLP 《Chinese Optics Letters》 (IF=3.5), MDPI 《Sensors》(IF=3.9), MDPI《Applied Sciences》(IF=2.7), 《Frontiers in Physics》(IF=3.1). Selected publications 名称 2024 [1] Jinfeng Hou, Xiaonan Liu, Yahui Liu, Ying He, Weijiang Zhao, Yufei Ma*. "Highly sensitive CO2-LITES sensor based on a self-designed low-frequency quartz tuning fork and fiber-coupled MPC". Chinese Optics Letters. 2024, 22(7), 073001 (Invited, SCI, IF=3.5). [2] Yahui Liu, Shunda Qiao, Chao Fang, Ying He, Haiyue Sun, Jian Liu, Yufei Ma*. "A highly sensitive LITES sensor based on a multi-pass cell with dense spot pattern and a novel quartz tuning fork with low frequency". Opto-Electronic Advances. 2024, 7(3), 230230 (SCI, IF=14.1). [3] Weipeng Chen, Shunda Qiao, Ying He, Jie Zhu, Kang Wang, Lei Qi, Sheng Zhou, Limin Xiao*, Yufei Ma*. "Mid-infrared all-fiber light-induced thermoelastic spectroscopy sensor based on hollow-core anti-resonant fiber. Photoacoustics". 2024, 36, 100594 (SCI, IF=7.9). [4] Tiantian Liang, Shunda Qiao, Yanjun Chen, Ying He, Yufei Ma*, "High-sensitivity methane detection based on QEPAS and H-QEPAS technologies combined with a self-designed 8.7 kHz quartz tuning fork". Photoacoustics. 2024, 36, 100592 (SCI, IF=7.9). [5] Chao Fang, Tiantian Liang, Shunda Qiao, Ying He, Zuochun Shen, Yufei Ma*. “Quartz-enhanced photoacoustic spectroscopy sensing using trapezoidal- and round-head quartz tuning forks”. Optics Letters. 2024, 49(3), 770-773 (SCI, IF=3.6, Editor’s Pick). [6] Ziting Lang, Shunda Qiao, Tiantian Liang, Ying He, Lei Qi, and Yufei Ma*. “Dual-frequency modulated heterodyne quartzenhanced photoacoustic spectroscopy”. Optics Express. 2024, 32(1), 379-386 (SCI, IF=3.894) [7] Chu Zhang, Shunda Qiao, Ying He, and Yufei Ma*. “Trace gas sensor based on a multi-pass-retro-reflection-enhanced differential Helmholtz photoacoustic cell and a power amplified diode laser”. Optics Express. 2024, 32(1), 848-856 (SCI, IF=3.894) 2023 [1] Yufei Ma*, Tiantian Liang, Shunda Qiao, Xiaonan Liu, and Ziting Lang. “Highly sensitive and fast hydrogen detection based on light-induced thermoelastic spectroscopy”. Ultrafast Science. 2023, 3, 0024 (Science serial journal). [2] Ziting Lang, Shunda Qiao and Yufei Ma*. “Fabry–Perot-based phase demodulation of heterodyne light-induced thermoelastic spectroscopy”. Light: Advanced Manufacturing. 2023, 4, 23. (Light serial journal). [3] Chu Zhang, Shunda Qiao, Ying He, Sheng Zhou, Lei Qi, and Yufei Ma*. “Differential quartz-enhanced photoacoustic spectroscopy”. Applied Physics Letters. 2023, 122(24), 241103 (SCI, IF=4.0, Editor’s Pick) [4] Yahui Liu and Yufei Ma*. "Advances in multipass cell for absorption spectroscopy-based trace gas sensing technology". Chinese Optics Letters. 2023, 21(3), 033001 (SCI, IF=3.5, Invited)[5] Shunda Qiao, Pengze Ma, Viktor Tsepelin, Guowei Han, Jinxing Liang, Wei Ren, Huadan Zheng, Yufei Ma*. Super tiny quartz-tuning-fork-based light-induced thermoelastic spectroscopy sensing. Optics Letters. 2023, 48(2), 419-422 (SCI, IF=3.866, Editor’s Pick). [6] Weipeng Chen, Shunda Qiao, Ziting Lang, Jiachen Jiang, Ying He, Yiwei Shi, and Yufei Ma*. “Hollow-waveguide-based light-induced thermoelastic spectroscopy sensing”. Optics Letters. 2023, 48(15), 3989-3992. (SCI, IF=3.866) [7] Chu Zhang, Ying He, Shunda Qiao, Yufei Ma*. “Differential integrating sphere based photoacoustic spectroscopy gas sensing”. Optics Letters. 2023, 48(19), 5089-5092. (SCI, IF=3.866) [8] Xiaonan Liu, Yufei Ma*. “New temperature measurement method based on light-induced thermoelastic spectroscopy.” Optics Letters. 2023, 48(21), 5687-5690. (SCI, IF=3.866) [9] Ziting Lang, Shunda Qiao, Tiantian Liang, Ying He, Lei Qi, and Yufei Ma*. “Dual-frequency modulated heterodyne quartzenhanced photoacoustic spectroscopy”. Optics Express. 2023. (SCI, IF=3.894) [10] Cunguang Lou, Jialiang Dai, Yaxin Wang, Yu Zhang, Yifan Li, Xiuling Liu, Ruikai Li, Yufei Ma*. “Quartz tuning fork-based high sensitive photodetector by co-coupling photoelectric and the thermoelastic effect of perovskite.” Optics Express. 2023, 31(6), 10027-10037. (SCI, IF=3.894) [11] Chu Zhang, Shunda Qiao, Yufei Ma*. “Highly sensitive photoacoustic acetylene detection based on differential photoacoustic cell with retro-reflection-cavity.” Photoacoustics. 2023, 30, 100467. (SCI, IF=9.656). [12] Cunguang Lou, Jialiang Dai, Yaxin Wang, Yu Zhang, Yifan Li, Xiuling Liu*, Yufei Ma*. “Highly sensitive light-induced thermoelastic spectroscopy oxygen sensor with co-coupling photoelectric and thermoelastic effect of quartz tuning fork”. Photoacoustics. 2023, 31, 100515. (SCI, IF=9.656) 2022 [1] Yufei Ma*, Yinghao Hong, Shunda Qiao, Ziting Lang, Xiaonan Liu. “H-shaped acoustic micro-resonator based quartz-enhanced photoacoustic spectroscopy”. Optics Letters. 2022, 47(3), 601-604. [2] Ziting Lang, Shunda Qiao, Yufei Ma*. “Acoustic microresonator based in-plane quartz-enhanced photoacoustic spectroscopy with a line interaction mode”. Optics Letters. 2022, 47(6), 1295-1298. [3] Cunguang Lou, Xin Liu, Yu Wang, Yu Zhang, Yifan Li, Jianquan Yao, Chao Chang, Yufei Ma*, et al. “Ultra-broadband optical detection from visible to terahertz range using a miniature quartz tuning fork with soft prongs”. Optics Letters. 2022, 47(7), 1875-1878 (SCI, IF=3.866). [4] Xiaonan Liu, Shunda Qiao, Yufei Ma*. “Highly sensitive methane detection based on light-induced thermoelastic spectroscopy with a 2.33 μm diode laser and adaptive Savitzky-Golay filtering”. Optics Express. 2022, 30(2), 1304-1313. [5] Yufei Ma*, Yinqiu Hu, Shunda Qiao, Ziting Lang, Xiaonan Liu, Ying He, Vincenzo Spagnolo. “Quartz tuning forks resonance frequency matching for laser spectroscopy sensing”. Photoacoustics. 2022, 25, 100329. (SCI, IF=8.484) [6] Xiaonan Liu, Yufei Ma*. “Sensitive carbon monoxide detection based on light-induced thermoelastic spectroscopy with a fiber-coupled multipass cell.” Chinese Optics Letters. 2022, 20(3), 031201 (SCI, IF=2.448, Invited) [7] Tiantian Liang, Shunda Qiao, Ziting Lang, Yufei Ma*. “Highly sensitive trace gas detection based on in-plane single-quartz-enhanced dual spectroscopy.” Sensors. 2022, 22, 1035. (SCI, IF=3.576, Invited) 2021 [1] Shunda Qiao, Ying He, Yufei Ma*. “Trace gas sensing based on single-quartz-enhanced photoacoustic-photothermal dual spectroscopy”. Optics Letters. 2021, 46(10), 2449-2452 [2] Shunda Qiao, Yufei Ma*, Pietro Patimisco, Angelo Sampaolo, Ying He, Ziting Lang, Frank K. Tittel, Vincenzo Spagnolo. “Multi-pass quartz-enhanced photoacoustic spectroscopy based trace gas sensing”. Optics Letters. 2021, 46(5), 977-980. [3] Ziting Lang, Shunda Qiao, Ying He, Yufei Ma*. “Quartz tuning fork-based demodulation of an acoustic signal induced by photo-thermo-elastic energy conversion”. Photoacoustics. 2021, 22, 100272. (SCI, IF=8.484) [4] Yinqiu Hu, Shunda Qiao, Ying He, Ziting Lang, Yufei Ma*. “Quartz-enhanced photoacoustic-photothermal spectroscopy for trace gas sensing”. Optics Express. 2021, 29(4), 5121-5127. [5] Shunda Qiao, Yufei Ma*, Ying He, Pietro Patimisco, Angelo Sampaolo, Vincenzo Spagnolo. “Ppt level carbon monoxide detection based on light-induced thermoelastic spectroscopy exploring custom quartz tuning forks and a mid-infrared QCL”. Optics Express. 2021, 29(16), 25100-25108. [6] Cunguang Lou, Hongjia Chen, Xitong Li, Xu Yang, Yu Zhang, Jianquan Yao, Yufei Ma*, Chao Chang*, Xiuling Liu*. “Graphene oxide and polydimethylsiloxane coated quartz tuning fork for improved sensitive near- and mid-infrared detection”. Optics Express. 2021, 29(13), 20190-20204. [7] Yufei Ma*, Ziting Lang, Ying He, Shunda Qiao, Yu Li. “Ultra-highly sensitive hydrogen chloride detection based on quartz-enhanced photothermal spectroscopy”. Sensors. 2021, 21, 3563. (SCI, IF=3.576, Invited) [8] Wei Feng, Yanchen Qu, Yachen Gao, Yufei Ma*. “Advances in fiber-based quartz enhanced photoacoustic spectroscopy for trace gas sensing”. Microwave and Optical Technology Letters. 2021, 63, 2031-2039. (SCI, IF=1.392, Invited) 2020 [1] Yufei Ma*, Ying He, Pietro Patimisco, Angelo Sampaolo, Shunda Qiao, Xin Yu, Frank K. Tittel, Vincenzo Spagnolo. “Ultra-high sensitive trace gas detection based on light-induced thermoelastic spectroscopy and a custom quartz tuning fork.” Applied Physics Letters. 2020, 116, 011103. [2] Yufei Ma*, Shunda Qiao, Pietro Patimisco, Angelo Sampaolo, Yao Wang, Frank K. Tittel, Vincenzo Spagnolo. “In-plane quartz-enhanced photoacoustic spectroscopy.” Applied Physics Letters. 2020, 116, 061101. [3] Yufei Ma*, Yinqiu Hu, Shunda Qiao, Ying He, Frank K. Tittel. “Trace gas sensing based on multi-quartz-enhanced photothermal spectroscopy”. Photoacoustics. 2020, 20, 100206 (SCI, IF=8.484) [4] Yu Li, Ruozhu Wang, Frank K. Tittel, Yufei Ma*. “Sensitive methane detection based on quartz-enhanced photoacoustic spectroscopy with a high-power diode laser and wavelet filtering.” Optics and Lasers in Engineering. 2020, 132, 106155 (SCI, IF=4.836) [5] Yufei Ma*. “Recent advances in QEPAS and QEPTS based trace gas sensing: a review”. Frontiers in Physics. 2020, 8, 268 (SCI, IF=3.56, Invited) 2019 [1] Ying He, Yufei Ma*, Yao Tong, Xin Yu, Frank K. Tittel. “Ultra-high sensitive light-induced thermoelastic spectroscopy sensor with a high Q-factor quartz tuning fork and a multipass cell”. Optics Letters, 2019, 44(8), 1904-1907. [2] Yufei Ma*, Shunda Qiao, Ying He, Yu Li, Zhonghua Zhang, Xin Yu, Frank K. Tittel. “Highly sensitive acetylene detection based on multi-pass retro-reflection-cavity-enhanced photoacoustic spectroscopy and a fiber amplified diode laser”. Optics Express. 2019, 27(10), 14163-14172. [3] Yufei Ma*, Yao Tong, Ying He, Xingang Jin, Frank K. Tittel. “Compact and sensitive mid-infrared all-fiber quartz-enhanced photoacoustic spectroscopy sensor for carbon monoxide detection”. Optics Express. 2019, 27(6), 9302-9312. 2018 [1] Yufei Ma*, Ying He, Yao Tong, Xin Yu, Frank K. Tittel. “Quartz-tuning-fork enhanced photothermal spectroscopy for ultra-high sensitive trace gas detection.” Optics Express. 2018, 26(24), 32103-32110. [2] Yufei Ma*, Ying He, Ligong Zhang, Xin Yu, Jingbo Zhang, Rui Sun, Frank K. Tittel. “Ultra-high sensitive acetylene detection using quartz-enhanced photoacoustic spectroscopy with a fiber amplified diode laser and a 30.72 kHz quartz tuning fork”. Applied Physics Letters. 2017, 110, 031107. [3] Ying He, Yufei Ma*, Yao Tong, Xin Yu, Frank K. Tittel. “HCN ppt-level detection based on a QEPAS sensor with amplified laser and a miniaturized 3D-printed photoacoustic detection channel”. Optics Express. 2018, 26(8), 9666-9675. [4] Yufei Ma*. “Review of recent advances in QEPAS-based trace gas sensing”. Applied Sciences. 2018, 8, 1822. (SCI, IF=2.217, Invited) Before 2018 [1] Ying He, Yufei Ma*, Yao Tong, Xin Yu, Zhenfang Peng, Jing Gao, Frank K. Tittel. “Long distance, distributed gas sensing based on micro-nano fiber evanescent wave quartz-enhanced photoacoustic spectroscopy”. Applied Physics Letters. 2017, 111, 241102. [2] Yufei Ma*, Ying He, Xin Yu, Jingbo Zhang, Rui Sun, Frank K. Tittel. “Compact all-fiber quartz-enhanced photoacoustic spectroscopy sensor with a 30.72 kHz quartz tuning fork and spatially resolved trace gas detection”. Applied Physics Letters. 2016, 108, 091115. [3] Yufei Ma*, Xin Yu, Guang Yu, Xudong Li, Jingbo Zhang, Deying Chen, Rui Sun, Frank K. Tittel. “Multi-quartz-enhanced photoacoustic spectroscopy”. Applied Physics Letters. 2015, 107, 021106. [4] Yufei Ma*, Ying He, Yao Tong, Xin Yu, Frank K. Tittel. “Ppb-level detection of ammonia based on QEPAS using a power amplified laser and a low resonance frequency quartz tuning fork”. Optics Express. 2017, 25(23), 29356-29364. [5] Yufei Ma*, Ying He, Xin Yu, Cheng Chen, Rui Sun, Frank K. Tittel. “HCl ppb-level detection based on QEPAS sensor using a low resonance frequency quartz tuning fork”. Sensors and Actuators B. 2016, 233, 388-393. [6] Yufei Ma*, Ying He, Xin Yu, Xudong Li, Jiang Li, Renpeng Yan, Jiangbo Peng, Xinlu Zhang, Rui Sun, Yubai Pan, Deying Chen. “Multiple-beam, pulse-burst, passively Qswitched ceramic Nd:YAG laser under microlens array pumping”. Optics Express. 2015, 23(19), 24955-24961. (SCI, IF=3.587). [7] Yufei Ma*, Xudong Li, Xin Yu, Rongwei Fan, Renpeng Yan, Jiangbo Peng, Xinrui Xu, Rui Sun, Deying Chen. “A novel miniaturized passively Q-switched pulse-burst laser for engine ignition”. Optics Express. 2014, 22, 24655-24665. (SCI, IF=3.525). [8] Yufei Ma, Rafal Lewicki*, Manijeh Razeghi, Frank K. Tittel. “QEPAS based ppb-level detection of CO and N2O using a high power CW DFB-QCL”. Optics Express. 2013, 21(1), 1008-1019. 研究领域 名称 激光传感技术、激光光谱技术、固体激光技术。 1）光谱式气体传感技术是基于气体分子的“指纹”吸收光谱特性，通过测量与被测气体光谱特性相关的参数反演气体种类与浓度，因此具有选择性强、灵敏度高、响应迅速、非侵入式和在线测量等优点，是高性能气体传感研究的主流技术。本课题组长期从事各种类型的光谱传感技术，其中在石英光谱技术方面形成了自己的研究特色，主持了国家部委、华为公司委托的多个项目。 3D打印的小型化石英光谱传感单元 讲授课程 名称 研究生课程： 1. 现代光电子技术实验 2. 先进激光器件及应用前沿专题 本科生课程： 半导体激光器及应用 光电子器件课程设计 先进激光气体传感技术及其前沿应用 智能光谱传感技术实验 招生信息 名称 每年招收博士生、硕士生及本科生多名。 期刊论文 名称 本课题组发表的部分论文如下： 2024 [1] Jinfeng Hou, Xiaonan Liu, Yahui Liu, Ying He, Weijiang Zhao, Yufei Ma*. "Highly sensitive CO2-LITES sensor based on a self-designed low-frequency quartz tuning fork and fiber-coupled MPC". Chinese Optics Letters. 2024, 22(7), 073001 (Invited, SCI, IF=3.5). [2] Yahui Liu, Shunda Qiao, Chao Fang, Ying He, Haiyue Sun, Jian Liu, Yufei Ma*. "A highly sensitive LITES sensor based on a multi-pass cell with dense spot pattern and a novel quartz tuning fork with low frequency". Opto-Electronic Advances. 2024, 7(3), 230230 (SCI, IF=14.1). [3] Weipeng Chen, Shunda Qiao, Ying He, Jie Zhu, Kang Wang, Lei Qi, Sheng Zhou, Limin Xiao*, Yufei Ma*. "Mid-infrared all-fiber light-induced thermoelastic spectroscopy sensor based on hollow-core anti-resonant fiber. Photoacoustics". 2024, 36, 100594 (SCI, IF=7.9). [4] Tiantian Liang, Shunda Qiao, Yanjun Chen, Ying He, Yufei Ma*, "High-sensitivity methane detection based on QEPAS and H-QEPAS technologies combined with a self-designed 8.7 kHz quartz tuning fork". Photoacoustics. 2024, 36, 100592 (SCI, IF=7.9). [5] Chao Fang, Tiantian Liang, Shunda Qiao, Ying He, Zuochun Shen, Yufei Ma*. “Quartz-enhanced photoacoustic spectroscopy sensing using trapezoidal- and round-head quartz tuning forks”. Optics Letters. 2024, 49(3), 770-773 (SCI, IF=3.6, Editor’s Pick). [6] Ziting Lang, Shunda Qiao, Tiantian Liang, Ying He, Lei Qi, and Yufei Ma*. “Dual-frequency modulated heterodyne quartzenhanced photoacoustic spectroscopy”. Optics Express. 2024, 32(1), 379-386 (SCI, IF=3.894) [7] Chu Zhang, Shunda Qiao, Ying He, and Yufei Ma*. “Trace gas sensor based on a multi-pass-retro-reflection-enhanced differential Helmholtz photoacoustic cell and a power amplified diode laser”. Optics Express. 2024, 32(1), 848-856 (SCI, IF=3.894) 2023 [1] Yufei Ma*, Tiantian Liang, Shunda Qiao, Xiaonan Liu, and Ziting Lang. “Highly sensitive and fast hydrogen detection based on light-induced thermoelastic spectroscopy”. Ultrafast Science. 2023, 3, 0024. [2] Ziting Lang, Shunda Qiao and Yufei Ma*. “Fabry–Perot-based phase demodulation of heterodyne light-induced thermoelastic spectroscopy”. Light: Advanced Manufacturing. 2023, 4, 23. [3] Chu Zhang, Shunda Qiao, Ying He, Sheng Zhou, Lei Qi, and Yufei Ma*. “Differential quartz-enhanced photoacoustic spectroscopy”. Applied Physics Letters. 2023, 122(24), 241103 (SCI, IF=3.791, Editor’s Pick) [4] Yahui Liu and Yufei Ma*. "Advances in multipass cell for absorption spectroscopy-based trace gas sensing technology". Chinese Optics Letters. 2023, 21(3), 033001 (SCI, IF=3.5, Invited) [5] Shunda Qiao, Pengze Ma, Viktor Tsepelin, Guowei Han, Jinxing Liang, Wei Ren, Huadan Zheng, Yufei Ma*. Super tiny quartz-tuning-fork-based light-induced thermoelastic spectroscopy sensing. Optics Letters. 2023, 48(2), 419-422 (SCI, IF=3.866, Editor’s Pick). [6] Weipeng Chen, Shunda Qiao, Ziting Lang, Jiachen Jiang, Ying He, Yiwei Shi, and Yufei Ma*. “Hollow-waveguide-based light-induced thermoelastic spectroscopy sensing”. Optics Letters. 2023, 48(15), 3989-3992. (SCI, IF=3.866) [7] Chu Zhang, Ying He, Shunda Qiao, Yufei Ma*. “Differential integrating sphere based photoacoustic spectroscopy gas sensing”. Optics Letters. 2023, 48(19), 5089-5092. (SCI, IF=3.866) [8] Xiaonan Liu, Yufei Ma*. “New temperature measurement method based on light-induced thermoelastic spectroscopy.” Optics Letters. 2023, 48(21), 5687-5690. (SCI, IF=3.866) [9] Cunguang Lou, Jialiang Dai, Yaxin Wang, Yu Zhang, Yifan Li, Xiuling Liu, Ruikai Li, Yufei Ma*. “Quartz tuning fork-based high sensitive photodetector by co-coupling photoelectric and the thermoelastic effect of perovskite.” Optics Express. 2023, 31(6), 10027-10037. (SCI, IF=3.894) [10] Chu Zhang, Shunda Qiao, Yufei Ma*. “Highly sensitive photoacoustic acetylene detection based on differential photoacoustic cell with retro-reflection-cavity.” Photoacoustics. 2023, 30, 100467. (SCI, IF=9.656). [11] Cunguang Lou, Jialiang Dai, Yaxin Wang, Yu Zhang, Yifan Li, Xiuling Liu*, Yufei Ma*. “Highly sensitive light-induced thermoelastic spectroscopy oxygen sensor with co-coupling photoelectric and thermoelastic effect of quartz tuning fork”. Photoacoustics. 2023, 31, 100515. (SCI, IF=9.656) 2022 [1] Yufei Ma*, Yinghao Hong, Shunda Qiao, Ziting Lang, Xiaonan Liu. "H-shaped acoustic micro-resonator based quartz-enhanced photoacoustic spectroscopy". Optics Letters. 2022, 47(3), 601-604. [2] Ziting Lang, Shunda Qiao, Yufei Ma*. “Acoustic microresonator based in-plane quartz-enhanced photoacoustic spectroscopy with a line interaction mode”. Optics Letters. 2022, 47(6), 1295-1298. [3] Cunguang Lou, Xin Liu, Yu Wang, Yu Zhang, Yifan Li, Jianquan Yao, Chao Chang, Yufei Ma*, et al. “Ultra-broadband optical detection from visible to terahertz range using a miniature quartz tuning fork with soft prongs”. Optics Letters. 2022, 47(7), 1875-1878 (SCI, IF=3.866). [4] Xiaonan Liu, Shunda Qiao, Yufei Ma*. “Highly sensitive methane detection based on light-induced thermoelastic spectroscopy with a 2.33 μm diode laser and adaptive Savitzky-Golay filtering”. Optics Express. 2022, 30(2), 1304-1313. [5] Yufei Ma*, Wei Feng, Shunda Qiao, Zixu Zhao, Shoufei Gao, and Yingying Wang. “Hollow-core anti-resonant fiber based light-induced thermoelastic spectroscopy for gas sensing”. Optics Express. 2022, 30(11), 18836-18844. [6] Yufei Ma*, Yinqiu Hu, Shunda Qiao, Ziting Lang, Xiaonan Liu, Ying He, Vincenzo Spagnolo. “Quartz tuning forks resonance frequency matching for laser spectroscopy sensing”. Photoacoustics. 2022, 25, 100329. (SCI, IF=9.656) [7] Shunda Qiao, Angelo Sampaolo, Pietro Patimisco, Vincenzo Spagnolo, Yufei Ma*. Ultra-highly sensitive HCl-LITES sensor based on a low-frequency quartz tuning fork and a fiber-coupled multi-pass cell”. Photoacoustics. 2022, 27, 100381 (SCI, IF=9.656) [8] Xiaonan Liu, Shunda Qiao, Guowei Han, Jinxing Liang, Yufei Ma*. "Highly sensitive HF detection based on absorption enhanced light-induced thermoelastic spectroscopy with a quartz tuning fork of receive and shallow neural network fitting". Photoacoustics. 2022, 28, 100422 (SCI, IF=9.656) [9] Xiaonan Liu, Yufei Ma*. “Sensitive carbon monoxide detection based on light-induced thermoelastic spectroscopy with a fiber-coupled multipass cell.” Chinese Optics Letters. 2022, 20(3), 031201 (SCI, IF=2.56, Invited) [10] Tiantian Liang, Shunda Qiao, Ziting Lang, Yufei Ma*. “Highly sensitive trace gas detection based on in-plane single-quartz-enhanced dual spectroscopy.” Sensors. 2022, 22, 1035. (SCI, IF=3.847, Invited) 2021 [1] Shunda Qiao, Ying He, Yufei Ma*. “Trace gas sensing based on single-quartz-enhanced photoacoustic-photothermal dual spectroscopy”. Optics Letters. 2021, 46(10), 2449-2452 [2] Shunda Qiao, Yufei Ma*, Pietro Patimisco, Angelo Sampaolo, Ying He, Ziting Lang, Frank K. Tittel, Vincenzo Spagnolo. “Multi-pass quartz-enhanced photoacoustic spectroscopy based trace gas sensing”. Optics Letters. 2021, 46(5), 977-980. [3] Ziting Lang, Shunda Qiao, Ying He, Yufei Ma*. “Quartz tuning fork-based demodulation of an acoustic signal induced by photo-thermo-elastic energy conversion”. Photoacoustics. 2021, 22, 100272. (SCI, IF=9.656) [4] Yinqiu Hu, Shunda Qiao, Ying He, Ziting Lang, Yufei Ma*. “Quartz-enhanced photoacoustic-photothermal spectroscopy for trace gas sensing”. Optics Express. 2021, 29(4), 5121-5127. [5] Shunda Qiao, Yufei Ma*, Ying He, Pietro Patimisco, Angelo Sampaolo, Vincenzo Spagnolo. “Ppt level carbon monoxide detection based on light-induced thermoelastic spectroscopy exploring custom quartz tuning forks and a mid-infrared QCL”. Optics Express. 2021, 29(16), 25100-25108. [6] Cunguang Lou, Hongjia Chen, Xitong Li, Xu Yang, Yu Zhang, Jianquan Yao, Yufei Ma*, Chao Chang*, Xiuling Liu*. “Graphene oxide and polydimethylsiloxane coated quartz tuning fork for improved sensitive near- and mid-infrared detection”. Optics Express. 2021, 29(13), 20190-20204. [7] Yufei Ma*, Ziting Lang, Ying He, Shunda Qiao, Yu Li. “Ultra-highly sensitive hydrogen chloride detection based on quartz-enhanced photothermal spectroscopy”. Sensors. 2021, 21, 3563. (SCI, IF=3.847, Invited) [8] Wei Feng, Yanchen Qu, Yachen Gao, Yufei Ma*. “Advances in fiber-based quartz enhanced photoacoustic spectroscopy for trace gas sensing”. Microwave and Optical Technology Letters. 2021, 63, 2031-2039. (SCI, IF=1.392, Invited) 2020 [1] Yufei Ma*, Ying He, Pietro Patimisco, Angelo Sampaolo, Shunda Qiao, Xin Yu, Frank K. Tittel, Vincenzo Spagnolo. “Ultra-high sensitive trace gas detection based on light-induced thermoelastic spectroscopy and a custom quartz tuning fork.” Applied Physics Letters. 2020, 116, 011103. [2] Yufei Ma*, Shunda Qiao, Pietro Patimisco, Angelo Sampaolo, Yao Wang, Frank K. Tittel, Vincenzo Spagnolo. “In-plane quartz-enhanced photoacoustic spectroscopy.” Applied Physics Letters. 2020, 116, 061101. [3] Yufei Ma*, Yinqiu Hu, Shunda Qiao, Ying He, Frank K. Tittel. “Trace gas sensing based on multi-quartz-enhanced photothermal spectroscopy”. Photoacoustics. 2020, 20, 100206 (SCI, IF=8.484) [4] Yu Li, Ruozhu Wang, Frank K. Tittel, Yufei Ma*. “Sensitive methane detection based on quartz-enhanced photoacoustic spectroscopy with a high-power diode laser and wavelet filtering.” Optics and Lasers in Engineering. 2020, 132, 106155 (SCI, IF=4.836) [5] Yufei Ma*. “Recent advances in QEPAS and QEPTS based trace gas sensing: a review”. Frontiers in Physics. 2020, 8, 268 (SCI, IF=3.56, Invited) 2019 [1] Ying He, Yufei Ma*, Yao Tong, Xin Yu, Frank K. Tittel. “Ultra-high sensitive light-induced thermoelastic spectroscopy sensor with a high Q-factor quartz tuning fork and a multipass cell”. Optics Letters, 2019, 44(8), 1904-1907. [2] Yufei Ma*, Shunda Qiao, Ying He, Yu Li, Zhonghua Zhang, Xin Yu, Frank K. Tittel. “Highly sensitive acetylene detection based on multi-pass retro-reflection-cavity-enhanced photoacoustic spectroscopy and a fiber amplified diode laser”. Optics Express. 2019, 27(10), 14163-14172. [3] Yufei Ma*, Yao Tong, Ying He, Xingang Jin, Frank K. Tittel. “Compact and sensitive mid-infrared all-fiber quartz-enhanced photoacoustic spectroscopy sensor for carbon monoxide detection”. Optics Express. 2019, 27(6), 9302-9312. 2018 [1] Yufei Ma*, Ying He, Yao Tong, Xin Yu, Frank K. Tittel. “Quartz-tuning-fork enhanced photothermal spectroscopy for ultra-high sensitive trace gas detection.” Optics Express. 2018, 26(24), 32103-32110. [2] Yufei Ma*, Ying He, Ligong Zhang, Xin Yu, Jingbo Zhang, Rui Sun, Frank K. Tittel. “Ultra-high sensitive acetylene detection using quartz-enhanced photoacoustic spectroscopy with a fiber amplified diode laser and a 30.72 kHz quartz tuning fork”. Applied Physics Letters. 2017, 110, 031107. [3] Ying He, Yufei Ma*, Yao Tong, Xin Yu, Frank K. Tittel. “HCN ppt-level detection based on a QEPAS sensor with amplified laser and a miniaturized 3D-printed photoacoustic detection channel”. Optics Express. 2018, 26(8), 9666-9675. [4] Yufei Ma*. “Review of recent advances in QEPAS-based trace gas sensing”. Applied Sciences. 2018, 8, 1822. (SCI, IF=2.217, Invited) Before 2018 [1] Ying He, Yufei Ma*, Yao Tong, Xin Yu, Zhenfang Peng, Jing Gao, Frank K. Tittel. “Long distance, distributed gas sensing based on micro-nano fiber evanescent wave quartz-enhanced photoacoustic spectroscopy”. Applied Physics Letters. 2017, 111, 241102. [2] Yufei Ma*, Ying He, Xin Yu, Jingbo Zhang, Rui Sun, Frank K. Tittel. “Compact all-fiber quartz-enhanced photoacoustic spectroscopy sensor with a 30.72 kHz quartz tuning fork and spatially resolved trace gas detection”. Applied Physics Letters. 2016, 108, 091115. [3] Yufei Ma*, Xin Yu, Guang Yu, Xudong Li, Jingbo Zhang, Deying Chen, Rui Sun, Frank K. Tittel. “Multi-quartz-enhanced photoacoustic spectroscopy”. Applied Physics Letters. 2015, 107, 021106. [4] Yufei Ma*, Ying He, Yao Tong, Xin Yu, Frank K. Tittel. “Ppb-level detection of ammonia based on QEPAS using a power amplified laser and a low resonance frequency quartz tuning fork”. Optics Express. 2017, 25(23), 29356-29364. [5] Yufei Ma*, Ying He, Xin Yu, Cheng Chen, Rui Sun, Frank K. Tittel. “HCl ppb-level detection based on QEPAS sensor using a low resonance frequency quartz tuning fork”. Sensors and Actuators B. 2016, 233, 388-393. [6] Yufei Ma*, Ying He, Xin Yu, Xudong Li, Jiang Li, Renpeng Yan, Jiangbo Peng, Xinlu Zhang, Rui Sun, Yubai Pan, Deying Chen. “Multiple-beam, pulse-burst, passively Qswitched ceramic Nd:YAG laser under microlens array pumping”. Optics Express. 2015, 23(19), 24955-24961. (SCI, IF=3.587). [7] Yufei Ma*, Xudong Li, Xin Yu, Rongwei Fan, Renpeng Yan, Jiangbo Peng, Xinrui Xu, Rui Sun, Deying Chen. “A novel miniaturized passively Q-switched pulse-burst laser for engine ignition”. Optics Express. 2014, 22, 24655-24665. (SCI, IF=3.525). [8] Yufei Ma, Rafal Lewicki*, Manijeh Razeghi, Frank K. Tittel. “QEPAS based ppb-level detection of CO and N2O using a high power CW DFB-QCL”. Optics Express. 2013, 21(1), 1008-1019. 学生培养 名称 本课题组注重学生全方位、全过程培养，在读本科生累计在《Photoacoustics》、《Optics Express》、《Optical Materials Express》、《Laser Physics Letters》、《Sensors》等国际知名期刊上发表SCI检索学术论文9篇，在美国光学学会举办的Frontiers in Optics、Advanced Solid State Lasers等国际知名学术会议上发表EI检索学术论文5篇，本科生以第一作者申请国家发明专利1项；累计有5名学生担任美国光学学会(OSA)哈尔滨工业大学学生分会主席，4名学生担任副主席，4名学生担任秘书长。每年有≥1次全额资助去美国参加国际学术会议的机会。本课题组从第一批硕士毕业起(2017年)，到目前为止，培养的部分学生如下： 2023年： 3名学生获“第十一届全国大学生光电设计竞赛”国赛一等奖； 3名学生获“第十一届全国大学生光电设计竞赛东北区赛暨第七届东北地区大学生光电设计竞赛”一等奖并获路演银奖； 4支参赛队伍获“第十一届全国大学生光电设计竞赛东北区赛暨第七届东北地区大学生光电设计竞赛”一等奖； 2支参赛队伍获“第七届中国国际传感器创新创业大赛”东北赛区二等奖; 4支参赛队伍获“第八届黑龙江省大学生光电设计竞赛”一等奖； 1名学生获“黑龙江省优秀毕业生”荣誉称号； 1名学生获“哈尔滨工业大学优秀毕业生”荣誉称号； 2名学生获“哈尔滨工业大学优秀硕士论文”奖励； 1名学生获“博士研究生国家奖学金”； 1名学生获“硕士研究生国家奖学金”； 1名学生获“本科生国家奖学金”； 1名学生获“第一届光谱技术及应用大会”优秀学生论文奖； 1名学生获“中国电科十四所国睿奖学金”； 1名学生获第三届“光未来”研究生学术论坛三等奖。 2022年： 1名学生获得美国光学学会年度杰出审稿人荣誉称号； 1名学生获王大珩光学奖（光学类最高等级奖学金）； 1名学生获“博士研究生国家奖学金”； 1名学生获“硕士研究生国家奖学金”； 1名学生获全国光学与光学工程博士学术联赛东北赛区一等奖； 1名学生获全国光学与光学工程博士学术联赛全国分区赛季军； 2名学生获“哈尔滨工业大学优秀毕业生”荣誉称号； 1名本科生毕业设计获哈尔滨工业大学“校百优”； 1名学生获“哈尔滨工业大学优秀硕士论文”奖励； 4名学生获“第十届全国大学生光电设计竞赛东北区赛暨第六届东北地区大学生光电设计竞赛”一等奖； 4名学生获“第十届全国大学生光电设计竞赛”铜牌； 3名学生获第八届中国国际“互联网”大学生创新创业大赛省级银奖； 1名学生获中国电科十四所国睿博士研究生奖学金； 1名学生获华为奖学金； 1名学生获“光未来”研究生学术论坛优秀海报奖。 2021年： 1名学生获“研究生国家奖学金”; 1名学生获王大珩光学奖（光学类最高等级奖学金）； 1名学生获全国光学与光学工程博士学术联赛东北赛区第一名； 1名学生获“哈尔滨工业大学优秀硕士论文”奖励； 2名学生获“哈尔滨工业大学优秀毕业生”荣誉称号； 1名学生获“第五届全国激光光谱技术学术论坛”优秀报告奖； 1名学生获“第五届全国激光光谱技术学术论坛”优秀墙报奖； 1名大三学生在JCR 1区期刊上以第一作者身份发表学术论文1篇，并成功获得“清华大学”保研资格。 2020年： 1名学生毕业论文获哈尔滨工业大学“校优秀硕士生金奖”； 1名本科生毕业设计获哈尔滨工业大学“校百优”； 1名学生毕业设计获“校优秀”； 1名学生获全国激光光谱学术会议“优秀报告奖”； 2名学生获“中电莱斯奖学金”(奖金1W)； 1名学生获“航天科技集团CASC奖学金”(奖金1W)。 2019年： 1名学生获“博士研究生国家奖学金”； 2名学生获“硕士研究生国家奖学金”； 2名学生毕业论文获哈尔滨工业大学“校优秀硕士生金奖”； 1名本科生毕业设计获哈尔滨工业大学“校百优”； 1名学生获“哈尔滨工业大学优秀毕业生”荣誉称号。 2018年： 1名学生获“研究生国家奖学金”； 1名本科生毕业设计获哈尔滨工业大学“校百优”; 1名学生获“苏州育才奖学金”(奖金1W)。 2017年： 1名学生获“研究生国家奖学金”； 1名本科生毕业设计获哈尔滨工业大学“校百优”； 3名学生获得第十五届“挑战杯”黑龙江省大学生课外学术科技作品二等奖； 3名学生获得第七届“祖光杯”创意创新创业大赛银奖； 1名学生毕业设计获“校优秀”。