實驗室主任
唐榮林
文章來源: | 發(fā)布時間:2016-10-10 | 【打印】 【關(guān)閉】
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唐榮林,男,中國科學院地理科學與資源研究所 地理信息科學與技術(shù)全國重點實驗室 副主任、研究員、博士生導師,中國科學院大學崗位教授。曾獲“國家優(yōu)秀青年科學基金”資助、國家自然科學獎二等獎(序3/5)、“李小文遙感科學獎”等。
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研究領(lǐng)域和方向:
主要從事地表能量-水分-碳平衡組分/要素的遙感反演、驗證及應用研究。研究方向包括熱紅外遙感、水循環(huán)遙感、全球變化遙感、大數(shù)據(jù)分析與遙感智能建模等。
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教育背景:(倒序排列)
????●?2007年9月-2011年6月,中國科學院地理科學與資源研究所,博士
????●?2005年9月-2007年6月,武漢大學,碩士
????●?2001年9月-2005年6月,武漢大學,學士
工作經(jīng)歷:(倒序排列)
????●?2025.01-至今,中國科學院地理科學與資源研究所,地理信息科學與技術(shù)全國重點實驗室 研究員
????●?2017.12-2024.12,中國科學院地理科學與資源研究所,資源與環(huán)境信息系統(tǒng)國家重點實驗室 研究員
????●?2014.12-2017.11,中國科學院地理科學與資源研究所,資源與環(huán)境信息系統(tǒng)國家重點實驗室 副研究員
????●?2012.09-2014.11,中國科學院地理科學與資源研究所,資源與環(huán)境信息系統(tǒng)國家重點實驗室 助理研究員
????●?2011.08-2012.08,中國科學院地理科學與資源研究所 博士后
科研業(yè)績:
長期從事地表蒸散發(fā)遙感定量反演的基礎(chǔ)理論與方法研究。圍繞蒸散發(fā)遙感建模、模型參數(shù)化、時間尺度擴展、真實性檢驗等,共發(fā)表科技論文130余篇,其中SCI論文81篇,獲授權(quán)國家發(fā)明專利32項、實用新型專利2項,登記軟件著作權(quán)10項,參與制定國家標準7項。主持國家自然科學基金項目5項、中國科學院A類戰(zhàn)略性先導科技專項課題、京津冀環(huán)境綜合治理國家科技重大專項課題等項目/課題。獲國家自然科學獎二等獎、教育部自然科學獎二等獎、北京市自然科學獎二等獎等國家與省部級科技獎勵8項、行業(yè)學會科技獎勵3項、中國科學院優(yōu)秀博士學位論文等榮譽稱號。
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代表性學術(shù)論文:
[1]?Wang, J., *Tang Ronglin, Liu, M., Jiang, Y., Huang, L., & Li, Z. L. (2025). Coordinated estimates of 4-day 500 m global land surface energy balance components. Remote Sensing of Environment, 326, 114795.
[2]?Sun, Y., *Tang Ronglin, Huang, L., Liu, M., Jiang, Y., & Li, Z. L. (2025). Synergistic estimates of global 4-day 500 m gross primary production, evapotranspiration, and ecosystem water use efficiency from satellite data. Journal of Hydrology, 133506.
[3]?Jiang, Y., Zhao, J., Wu, A., Si, M., Bian, Z., *Tang Ronglin, & Li, Z. L. (2025). Optimizing latent heat flux calculation via composited thermal infrared temperatures. IEEE Transactions on Geoscience and Remote Sensing, 63, 4420311.
[4]?Tang Ronglin, Peng, Z., Liu, M., *Li, Z. L., Jiang, Y., Hu, Y., ... & Fisher, J. B. (2024). Spatial-temporal patterns of land surface evapotranspiration from global products. Remote Sensing of Environment, 304, 114066.
[5]?Tang Ronglin, Wang, Y., Jiang, Y., Liu, M., Peng, Z., Hu, Y., Huang, L., & Li, Z. L. (2024). A review of global products of air-sea turbulent heat flux: accuracy, mean, variability, and trend. Earth-Science Reviews, 249, 104662.
[6]?Wang, Y., *Tang Ronglin, Huang, L., Liu, M., Jiang, Y., & Li, Z. L. (2024). A Bowen ratio-informed method for coordinating the estimates of air–sea turbulent heat fluxes. Environmental Research Letters, 19(12), 124080.
[7]?Huang, L., Yuan, W., Zheng, Y., Zhou, Y., He, M., Jin, J., Huang, X., Chen, S., Liu, M., Guan, X., Jiang, S., Lin, X., Li, Z. L., *Tang Ronglin (2024). A dynamic-leaf light use efficiency model for improving gross primary production estimation. Environmental Research Letters, 19, 014066.
[8]?Peng, Z., *Tang, R. L., Liu, M., Jiang, Y., & Li, Z. L. (2023). Coupled estimation of global 500m daily aerodynamic roughness length, zero-plane displacement height and canopy height. Agricultural and Forest Meteorology, 342, 109754.
[9]?Wang, J., *Tang, R. L., Jiang, Y., Liu, M., & Li, Z. L. (2023). A practical method for angular normalization of global MODIS land surface temperature over vegetated surfaces. ISPRS Journal of Photogrammetry and Remote Sensing, 199, 289-304.
[10]?Hu, Y., *Tang, R. L., *Jiang, X., Li, Z. L., Jiang, Y., Liu, M., Gao, C., & Zhou, X. (2023). A physical method for downscaling land surface temperatures using surface energy balance theory. Remote Sensing of Environment, 286, 113421.
[11]?Tang, R. L., Li, Z. L., Liu, M., Jiang, Y., & Peng, Z. (2022). A moisture-based triangle approach for estimating surface evaporative fraction with time-series of remotely sensed data. Remote Sensing of Environment, 280, 113212.
[12]?Jiang, Y., *Tang, R. L., & Li, Z. L. (2022). A framework of correcting the angular effect of land surface temperature on evapotranspiration estimation in single-source energy balance models. Remote Sensing of Environment, 283, 113306.
[13]?Liu, M., *Tang, R. L., Li, Z. L., Duan, S., Gao, M., Xu, Z., & Song, L. (2022). Separating soil evaporation from vegetation transpiration by remotely sensed one-phase and two-phase trapezoids. Agricultural and Forest Meteorology, 327, 109215.
[14]?Huang, L., Lin, X., Jiang, S., Liu, M., Jiang, Y., Li, Z. L., & *Tang, R. L. (2022). A two-stage light use efficiency model for improving gross primary production estimation in agroecosystems. Environmental Research Letters, 17, 104021.
[15]?Jiang, Y., *Tang, R. L., & Li, Z. L. (2022). A physical full-factorial scheme for gap-filling of eddy covariance measurements of daytime evapotranspiration. Agricultural and Forest Meteorology, 323, 109087.
[16]?Peng, Z., *Tang, R. L., Jiang, Y., Liu, M., & Li, Z. L. (2022). Global estimates of 500 m daily aerodynamic roughness length from MODIS data. ISPRS Journal of Photogrammetry and Remote Sensing, 183, 336-351.
[17]?Jiang, Y., *Tang, R. L., & Li, Z. L. (2022). Reconstruction of daily evapotranspiration under cloudy sky constrained by soil water budget balance.?Journal of Hydrology, 605, 127288.
[18]?Tang, R. L., Li, Z.-L. (2017). An end-member-based two-source approach for estimating land surface evapotranspiration from remote sensing data. IEEE Transactions on Geoscience and Remote Sensing, 55(10), 5818-5832.
[19]?Tang, R. L., Li, Z.-L. (2017). An improved constant evaporative fraction method for estimating daily evapotranspiration from remotely sensed instantaneous observations. Geophysical Research Letters, 44(5), 2319-2326.
[20]?Tang, R. L., Li, Z.-L. (2017). Estimating daily evapotranspiration from remotely sensed instantaneous observations with simplified derivations of a theoretical model. Journal of Geophysical Research: Atmospheres, 122.
[21]?Tang, R. L., Li, Z.-L., Sun, X., Bi, Y. (2017). Temporal upscaling of instantaneous evapotranspirationon clear-sky days using the constant reference evaporative fraction method with fixed or variable surface. Journal of Geophysical Research: Atmospheres, 122, 784~801.
[22]?Tang, R. L., Li, Z.-L. (2015). Evaluation of two end-member-based models for regional land surface evapotranspiration estimation from MODIS data. Agricultural and Forest Meteorology, 202, 69-82.
[23]?Tang, R. L., Li, Z.-L., Sun, X. (2013). Temporal upscaling of instantaneous evapotranspiration: An intercomparison of four methods using eddy covariance measurements and MODIS data. Remote Sensing of Environment, 138, 102-118.
[24]?Tang, R. L., Li, Z.-L., Chen, K. S., Jia, Y., Li, C., Sun, X. (2013). Spatial-scale effect on the SEBAL model for evapotranspiration estimation using remote sensing data. Agricultural and Forest Meteorology, 174, 28-42.
[25]?Tang, R. L., Li, Z.-L., Jia, Y., Li, C., Sun, X., Kustas, W. P., Anderson, M. C. (2011). An intercomparison of three remote sensing-based energy balance models using Large Aperture Scintillometer measurements over a wheat–corn production region. Remote Sensing of Environment, 115(12), 3187-3202.
[26]?Tang, R. L., Li, Z.-L., Chen, K.-S. (2011). Validating MODIS‐derived land surface evapotranspiration with in situ measurements at two AmeriFlux sites in a semiarid region. Journal of Geophysical Research: Atmospheres, 116(D4).
[27]?Tang, R. L., Li, Z.-L., Tang, B. (2010). An application of the Ts–VI triangle method with enhanced edges determination for evapotranspiration estimation from MODIS data in arid and semi-arid regions: Implementation and validation. Remote Sensing of Environment, 114(3), 540-551.
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研究生招生與培養(yǎng):
招生專業(yè):地圖學與地理信息系統(tǒng)
招生方向:熱紅外遙感、地表能量-水分-碳平衡遙感、遙感大數(shù)據(jù)與智能建模
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聯(lián)系方式:010-64888172,tangrl@lreis.ac.cn , trl_wd@163.com
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