邱 博
副教授
Email: qiubo@nju.edu.cn
太阳成集团tyc234cc仙林校区大气楼A208
个人简介
| 邱博,太阳成集团tyc234cc副教授、硕士生导师,主要从事生态气象学相关研究。在国际主流学术期刊上发表学术论文40余篇,其中以第一/通讯(含共同)作者身份在Nature Sustainability、GRL等期刊发表论文20篇,研究成果入选2025年度中国气候研究重大进展、关键地球物质循环前沿科学中心一流科研成果奖、Nature Ecology & Evolution等期刊研究亮点。获得太阳成集团tyc234cc教师教学竞赛一等奖(2024年),指导员工获得第十九届“挑战杯”全国老员工课外学术科技作品竞赛“揭榜挂帅”专项赛全国一等奖、AGU年会“杰出员工报告奖(OSPA)”、国家奖学金等奖项。 |
教育经历
| 2016.12 | 太阳成集团tyc234cc,大气科学专业,理学博士 |
| 2011.06 | 南京信息工程大学,大气科学专业,理学学士 |
工作经历
| 2021.02至今 | 太阳成集团tyc234cc,副教授 |
| 2017.01—2021.01 | 太阳成集团tyc234cc国际地球系统科学研究所,助理研究员 |
主要科研项目
国家自然科学基金面上基金“叶绿素荧光冠层辐射传输模型的发展与应用”(2022.01-2025.12),主持
国家自然科学基金青年基金“陆面模式中高计算效率叶绿素荧光模型的发展研究”(2018.01-2020.12),主持
国家重点研发计划课题“耦合人类活动的陆面物理过程建模”,2017.07-2022.06,骨干
国家重点研发计划课题“基于动力降尺度的东亚气候响应的精细结构及高敏感区”,2017.07-2022.06,骨干
代表性论文
[20] Chen, J., Qiu, B.*, Chakraborty, T. C., Miao, X., Cao, Y., Li, L., ... & Guo, W.* (2025). Contrasting effects of urbanization on vegetation between the Global South and Global North. Nature Sustainability, 8(4), 373–384. (Nature Ecology & Evolution Research Highlights, ESI highly-cited paper)
[19] Chen, J., Qiu, B.*, Guo, W., Miao, X., Cao, Y., Zhao, Z., ... & Yang, L. (2025). Urban vegetation productivity under climate change and increasing urbanization: Insights from both urban-rural comparison and trend analysis for global cities. Urban Forestry & Urban Greening, 128950.
[18] Ni, Y., Qiu, B.*, Cao, Y., Miao, X., Li, L., Chen, J., ... & Guo, W. (2025). Divergent dominant physical processes of extreme heatwaves in northern and southern China. Climate Dynamics, 63(4), 188.
[17] Ding, S., Qiu, B.*, Luo, Y. (2025). Co-benefits of aerosol pollution mitigation in enhancing solar photovoltaic power generation in China. Environmental Research Letters, 20, 104055.
[16] Li, L., Wang, Z., Qiu, B.*, Huang, X.*, Guo, W., Miao, X., ... & Ding, A. (2024). Terrestrial carbon sink and clean air co‐benefits from China's carbon neutrality policy. Earth's Future, 12(10), e2024EF004631.
[15] Tian, X., Qiu, B.*, Ni, Y., Chen, J., Li, L., Cao, Y., & Zhao, S. (2024). Divergent response of energy exchange to heatwaves from flux tower observations among various vegetation types. Environmental Research Letters, 19(9), 094029.
[14] Ni, Y., Qiu, B.*, Miao, X., Li, L., Chen, J., Tian, X., ... & Guo, W.* (2024). Shift of soil moisture-temperature coupling exacerbated 2022 compound hot-dry event in eastern China. Environmental Research Letters, 19(1), 014059. (ERL Editor’s Choice, Highlights 2024)
[13] Chen, J., Qiu, B.*, Guo, W., Li, L., & Miao, X. (2023). Divergent response of crops and natural vegetation to the record-breaking extreme precipitation event in 2020 modulated by topography. Environmental Research Letters, 18(6), 064047.
[12] Kang, Z., Qiu, B.*, Xiang, Z., Liu, Y., Lin, Z., & Guo, W.* (2022). Improving simulations of vegetation dynamics over the Tibetan Plateau: Role of atmospheric forcing data and spatial resolution. Advances in Atmospheric Sciences, 39(7), 1115-1132.
[11] Li, L., Qiu, B.*, Guo, W., Zhang, Y., Song, Q., & Chen, J. (2022). Phenological and physiological responses of the terrestrial ecosystem to the 2019 drought event in Southwest China: Insights from satellite measurements and the SSiB2 model. International Journal of Applied Earth Observation and Geoinformation, 111, 102832.
[10] Li, W., Qiu, B.*, Guo, W., & Hsu, P. C. (2021). Rapid response of the East Asian trough to Tibetan Plateau snow cover. International Journal of Climatology, 41(1), 251-261.
[9] Qiu, B.*, Ge, J.*, Guo, W., Pitman, A. J., & Mu, M. (2020). Responses of Australian dryland vegetation to the 2019 heat wave at a subdaily scale. Geophysical Research Letters, 47, e2019GL086569.
[8] Qiu, B., Huang, A.*, Shi, X., Dai, Y., Wei, N., Guo, W., et al. (2020). Implementation and evaluation of an improved lake scheme in Beijing Climate Center Atmosphere‐Vegetation Interaction Model. Journal of Geophysical Research: Atmospheres, 125, e2019JD031272.
[7] Qiu, B., Chen, J. M., Ju, W., Zhang, Q., & Zhang, Y.* (2019). Simulating emission and scattering of solar-induced chlorophyll fluorescence at far-red band in global vegetation with different canopy structures. Remote Sensing of Environment, 233, 111373.
[6] Qiu, B., Li, W., Wang, X., Shang, L., Song, C., Guo, W., & Zhang, Y.* (2019). Satellite-observed solar-induced chlorophyll fluorescence reveals higher sensitivity of alpine ecosystems to snow cover on the Tibetan Plateau. Agricultural and Forest Meteorology, 271, 126–134.
[5] Wang, X., Qiu, B.*, Li, W., & Zhang, Q. (2019). Impacts of drought and heatwave on the terrestrial ecosystem in China as revealed by satellite solar-induced chlorophyll fluorescence. Science of the Total Environment, 693, 133627.
[4] Qian, X., Qiu, B.*, & Zhang, Y. (2019). Widespread Decline in Vegetation Photosynthesis in Southeast Asia Due to the Prolonged Drought During the 2015/2016 El Niño. Remote Sensing, 11, 910.
[3] Qiu, B., Xue, Y.*, Fisher, J. B., Guo, W., Berry, J. A., & Zhang, Y. (2018). Satellite Chlorophyll Fluorescence and Soil Moisture Observations Lead to Advances in the Predictive Understanding of Global Terrestrial Coupled Carbon-Water Cycles. Global Biogeochemical Cycles, 32, 360–375.
[2] Qiu, B., Guo, W. *, Xue, Y.*, & Dai, Q. (2016). Implementation and evaluation of a generalized radiative transfer scheme within canopy in the soil‐vegetation‐atmosphere transfer (SVAT) model. Journal of Geophysical Research: Atmospheres, 121, 12145–12163.
[1] 邱博, 郭维栋. (2022) 叶绿素荧光遥感在陆地生态系统碳循环和陆气相互作用中的应用研究进展. 大气科学学报, 45(6), 801–814.