北京大学 Doctoral Degree in Science
吉林大学 Bachelor's Degree in Science
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靳茜芃,副教授,硕士生导师,入选龙山学者支持计划、江苏省双创博士。2023年博士毕业于北京大学,曾获北京市优秀毕业生、北京大学优秀毕业生、北京大学校长奖学金等荣誉。
2023年入职南京信息工程大学环境科学与工程学院,加入大气环境和气候变化研究团队(PI:廖宏教授)。主要从事大气边界层与空气污染研究,近五年发表SCI论文20余篇,主持国家基金委青年基金项目、科技部基础资源调查专项子课题、科技部重点研发子课题、江苏省青年基金项目等多个项目。
研究兴趣
大气边界层是直接受地表强迫的对流层最底部大气,同时也是人类生产生活的主要场所,污染物的排放、传输、化学反应大部分发生在这一层,边界层的热动力结构及其与上层大气的垂直交换直接影响着空气污染的形成发展过程及其空间分布规律。我们致力于从大气边界层角度揭秘PM2.5和臭氧污染演变规律、分布形势、及其与天气气候相互作用,研究兴趣包括但不限于:
1、空气污染成因分析
2、边界层与自由大气垂直交换及其对空气污染的影响
3、气溶胶垂直分布及其辐射环境效应
4、大气环境数值模拟
主讲课程
《大气污染与气候变化》、《大气化学》、《大气环境数值模拟》
教育工作经历
2023.12-现在 南京信息工程大学,环境科学与工程学院,副教授
2024.07-2024.08 哈佛大学,工程与应用科学学院,交流访问
2023.08-2023.12 南京信息工程大学,环境科学与工程学院,讲师
2018.09-2023.07 北京大学,环境科学与工程学院,理学博士
2014.09-2018.06 吉林大学,新能源与环境学院,理学学士
学生培养
韩昱帆(2024年入学,硕士生,在读)
唐慧颖(2023年入学,本科生,大学生创新创业训练计划 省级立项)
每年计划招收硕士生2名,期待你的加入!
科研项目
国家自然科学基金青年科学基金项目(C类),主持,2025.01-2027.12
国家科技部科技基础资源调查专项—中国人工影响天气飞机多源探测数据集研制及示范应 用,子课题负责人,2026.01-2028.12
国家科技部重点研发计划—我国东部复杂地形和特大城市大气边界层与污染过程生消相互 影响机制研究,子课题负责人,2024.01-2026.12
江苏省自然科学基金青年基金项目,主持,2024.07-2027.06
已发表论文
2026
[22] Guan, Y. Q, Zhu, J., Wang, X. Q., Chen, L., Jin, X. P., Yue, X., & Liao, H.: Impact of tropospheric ozone-radiation interactions on summer ozone air quality over eastern China during 2010–2019. Atmospheric Research, 108817, 2026.
2025
[21] Qu, K., Wang, X. S., Yan, Y., Jin, X. P., He, L. Y., Huang, X. F., Cai, X. H., Shen, J., Peng, Z. M., Xiao, T., Vrekoussis, M., Kanakidou, M., Brasseur, G. P., Daskalakis, N., Zeng, L. M., & Zhang, Y. H.: Unexpectedly persistent PM2.5 pollution in the Pearl River Delta, South China, in the 2015–2017 cold seasons: the dominant role of meteorological changes during the El Niño-to-La Niña transition over emission reduction, Atmospheric Chemistry and Physics, 25:16983-17007, 2025.
[20] Wang, X. Q., Zhu, J., Jiao, G. C., Chen, X., Yang, Z. J,, Chen, L., Jin, X. P., & Liao, H.: Meteorological influence on surface ozone trends in China: assessing uncertainties caused by multi-dataset and multi-method, Atmospheric Chemistry and Physics, 25, 13863-13878, 2025.
[19] Li, B. J., Liao, H., Li, K., Lin, J. T., Gong, C., Liu, H., Li, Y., Chen, L., Yang, Y., Jin, X. P., Zhao, Y. Q., Wang, T., Jin, J. B., Dang, R. J., & Jacob Daniel J.: Environmental burden and health inequity in China’s road-based express delivery. Nature Cities, 2, 825-834, 2025.
[18] Chen, X., Li, K., Yang, T., Jin, X. P., Chen, L., Yang, Y., Zhao, S. M., Hu, B., Zhu, B., Wang, Z., F. & Liao, H.: Simulated photochemical response to observational constraints on aerosol vertical distribution over North China, Atmospheric Chemistry and Physics, 25, 9151-9168, 2025.
[17] Liu, C., Chen, L., Li, K., Jin, X. P., Chen, X., Qiao, W. H., & Liao, H.: Historical and future climate changes impact global solar photovoltaic power potential: Role of key meteorological variables. Atmospheric and Oceanic Science Letters, 18, 2025.
2024
[16] Qi, C. N., Wang, P. Y., Yang, Y., Li, H. M., Zhang, H., Ren, L. L., Jin, X. P., Zhan, C. C., Tang, J. P., & Liao, H.: Impacts of tropical cyclone–heat wave compound events on surface ozone in eastern China: comparison between the Yangtze River and Pearl River deltas, Atmospheric Chemistry and Physics, 24, 11775-11789, 2024.
[15] Jin, X. P., Cai, X. H., Wang, X. S., Huang, Q. Q., Song, Y., Kang, L., Zhang, H. S., & Zhu, T.: Water vapour exchange between the atmospheric boundary layer and free troposphere over eastern China: seasonal characteristics and the El Niño–Southern Oscillation anomaly. Atmospheric Chemistry and Physics, 24: 259-274, 2024.
[14] Jin, X. P., Cai, X. H., Li, Q. H., Zhang, H. S., Song, Y., Wang, X. S., & Zhu, T.: Observational evaluation of estimated air exchange flux between atmospheric boundary layer and free troposphere with WRF model. Journal of Geophysical Research-Atmospheres, 129: e2023JD039676, 2024.
[13] Qu, K., Yan, Y., Wang, X. S., Jin, X. P., Vrekoussis, M., Kanakidou, M., Brasseur, G. P., Lin, T. K., Xiao, T., Cai, X. H., Zeng, L. M., & Zhang, Y. H.: The effect of cross-regional transport on ozone and particulate matter pollution in China: A review of methodology and current knowledge.Science of the Total Environment, 947, 2024.
[12] Liu, M. X., Song, Y., Wang, T. T., Dang. X. Y., Shang, F., Jin, X. P., Di, M. L., Wang, W. G., Sun, Y. L., Zhang, Q., Kang, L., Cai, X. H., Zhan, H. S., & Zhu, T.: Can we reach consensus on the dominant sulfate formation pathway in China's haze?, PNAS Nexus, 3: 291, 2024.
2023
[11] Yan. Y,, Cai, X. H., Jin, X. P., Kang, L., Zhang, H. S., & Song, Y.: Planetary boundary layer climatological features over North China Plain: derived from intensive experiment data. International Journal of Climatology, 43:2568-2585, 2023.
[10] Qu, K., Wang, X. S., Cai, X. H., Yan, Y., Jin, X. P., Vrekoussis, M., Kanakidou, M., Brasseur, G. P., Shen, J., Xiao, T., Zeng, L. M., & Zhang, Y. H.: Rethinking the role of transport and photochemistry in regional ozone pollution: insights from ozone concentration and mass budgets. Atmospheric Chemistry and Physics, 23: 7653-7671, 2023.
[9] Li, Q. H., Zhang, H. S., Zhang, X. Y., Cai, X. H., Jin, X. P., Zhang, L., Song, Y., Hu, F., & Zhu, T.: COATS: Comprehensive observation on the atmospheric boundary layer three-dimensional structure during haze pollution in the North China Plain. Science China Earth Sciences, 66: 1-20, 2023.
[8] Hu, X., Cai, H. X., Cai, Y. J., Bai, H. D., Wang, X. B., Jin, X. P., Yan, Y., Yu, M. Y., & Song, Y: Sub-synoptic evolution of PM2.5 pollution patterns in the Huaihe River Basin, China. Atmospheric Pollution Research, 14: 101679, 2023.
2022
[7] Jin, X. P., Cai, X. H., Huang, Q. Q., Wang, X. S., Song, Y., Kang, L., & Zhang, H. S.: PM2.5 exchange between atmospheric boundary layer and free troposphere in North China Plain and its long-range transport effects. Journal of Geophysical Research-Atmospheres, 127: e2022JD037410, 2022.
[6] Jin, X. P., Cai, X. H., Yu, M. Y., Song, Y., Wang, X. S., Zhang, H. S., & Zhu, T.: Regional PM2.5 pollution confined by atmospheric internal boundaries in the North China Plain: boundary layer structures and numerical simulation. Atmospheric Chemistry and Physics, 22: 11409-11427, 2022.
[5] Jin, X. P., Cai, X. H., Yu, M. Y., Wang, X. B., Song, Y., Wang, X. S., Zhang, H. S., & Zhu, T.: Regional PM2.5 pollution confined by atmospheric internal boundaries in the North China Plain: Analysis based on surface observations. Science of the Total Environment, 841: 156728, 2022.
[4] Li, Q. H., Zhang, H. S., Jin, X. P., Cai, X. H., & Song, Y.: Mechanism of haze pollution in summer and its difference with winter in the North China Plain. Science of the Total Environment, 806: 150625, 2022.
2021及以前
[3] Jin, X. P., Cai, X. H., Huang, Q. Q., Wang, X. S., Song, Y., & Zhu, T.: Atmospheric boundary layer-free troposphere air exchange in the North China Plain and its impact on PM2.5 pollution. Journal of Geophysical Research-Atmospheres, 126: e2021JD034641, 2021.
[2] Jin, X. P., Cai, X. H., Yu, M. Y., Wang, X. S., Song, Y., Kang, L., Zhang, H. S., & Zhu, T.: Mesoscale structure of the atmospheric boundary layer and its impact on regional air pollution: A case study. Atmospheric Environment, 258: 118511, 2021.
[1] Jin, X. P., Cai, X. H., Yu, M. Y., Song, Y., Wang, X. S., Kang, L., & Zhang, H. S.: Diagnostic analysis of wintertime PM2.5 pollution in the North China Plain: The impacts of regional transport and atmospheric boundary layer variation. Atmospheric Environment, 224: 117346, 2020.
