基本介绍

教授,博士,中山大学“百人计划二期”引进人才。2001年毕业于中国科学院地理科学与资源环境研究所获理学博士学位;2008年於美国俄勒冈大学获第二个理学博士学位。2008至2010在美国佛蒙特大学植被生物系从事博士后研究。回国前,在美国内华达沙漠研究所地球与生态系统科学部做助理研究教授。研究兴趣主要包括:1)全球变化生态学, 2)生物地球化学循环,3)计算模拟,4)嵌入式生态感知与数据采集技术。研究成果(第一作者)曾发表在Global Ecology and Biogeography, Global Biogeochemical Cycles, Biogeosciences, Diversity and Distribution, Journal of Geophysical Research, Hydrology and Earth System Sciences,Journal of Hydrology, Climatic Change, Ecohydrology, Ecosphere, Progress in Physical Geography等SCI刊物上。

合作领域:热烈欢迎对全球变化生态学、生态水文学、生物地球化学循环、计算模拟、嵌入式生态感知与数据采集技术等感兴趣的博士后专职科研人员来中山大学合作!

招生方向:全球变化生态学、生态水文学、生物地球化学循环、计算模拟、嵌入式生态感知与数据采集技术

社会任职

广东省粤北岩溶区碳水耦合野外科学观测研究站 站长 (2023-至今)

中山大学土地中心 主任  (2022.10-2026.06)

地理科学与规划学院国土资源与环境系 主任 (2019.10-2022.6)

中国自然资源学会资源工程专委会  副主任 (2021-2025)

中国自然地理学专业委员会  委员 (2019-2025)

广东省党外知识分子联谊会  常务理事 (2021-2025)

 

人才招聘:欢迎海内外在全球变化生态学、生态水文学、生物地球化学循环、计算模拟、嵌入式生态感知与数据采集技术等方向感兴趣的青年才俊以博士后、专职科研人员身份加入。联系方式:tanggp3@mail.sysu.edu.cn 或 01-86-18824109677。

研究方向

1. 流域尺度生物地球化学循环
在流域尺度上,系统研究水循环过程中溶解性物质的产生、迁移及其对水质的影响,重点解析碳、水等物质在“地表水—土壤—地下水”界面的迁移转化规律与来源贡献。研究方法上,综合应用野外采样与高频原位监测,获取高时间分辨率的水文水化学数据,并结合室内实验分析与同位素示踪技术,精确示踪不同水源及溶质(如DOC、氮、磷等)的输送路径与转化机制。此外,借助分布式生态水文模型,将上述多源数据与模型过程相耦合,定量探讨流域尺度上水文过程、水环境演变与陆地生态过程之间的相互作用及反馈机制。

2. 全球变化与陆地生态系统
研究以气温升高等为代表的环境变化对陆地生态系统的影响,具体包括:生态系统结构(如植被组成与空间分布)、生态系统功能(如碳—水交换、植被生长)以及生物地球化学过程(如微生物分解、营养盐转化等)。研究方法包括:(i)通过野外实验揭示生态系统动态及其响应机理;(ii)利用分布式模型将观测结果从样地尺度推至区域或全球尺度,揭示生态系统过程的空间格局。

3. 分布式生态水文模型研发与应用
开发能够精细模拟陆地生态水文过程的计算机模型与软件平台。核心研发内容包括:构建可模拟生态水文耦合过程(如将光合作用等碳循环过程与蒸散发、土壤水分变化相耦合)、土壤生物地球化学过程(如有机制分解、营养盐迁移转化及CO₂等温室气体排放),以及植被—水分相互作用(如水分胁迫下植被的生理响应及其对水循环的反馈)的分布式计算机模拟模型与软件。

4. 嵌入式生态感知与数据采集技术
面向野外环境监测的实际需求,研发低功耗、高可靠性的嵌入式数据采集与传感系统。具体包括:(1)智能数据采集器研发:基于ARM或单片机,开发多通道信号采集电路,支持多种传感器接入,并配套固件实现数据存储、时间同步与远程传输;(2)生态与水文传感器研发:研发适用于复杂环境的低成本、高稳定性传感器,提升长期野外观测的数据质量。通过软硬件协同设计,构建从感知、采集到传输的一体化嵌入式解决方案,支撑生态水文过程的长期自动化监测。

学历背景

2001.09 至 2008.08:美国俄勒冈大学地理系,博士;博士导师:Prof. Patrick J. Bartlein

1998.09 至 2001.07:中国科学院地理科学与自然资源研究所,博士; 博士导师:刘燕华、李秀彬  研究员

1995.09 至 1998.07:北京师范大学环境科学研究院,硕士;硕士导师:杨志峰 教授 院士

1989.09 至 1993.07:湖南师范大学地理系,学士

工作经历

2015.03 至今:中山大学地理科学与规划学院水资源与环境系,教授

2011.09 至 2015.02:美国内华达沙漠研究所地球与生态科学部,助理研究教授

2010.09 至 2011.08:美国纽约城市大学亨特学院,助理研究员

2008.09 至 2010.08:美国佛蒙特大学植被生物系,博士后;指导老师:Prof. Brian D. Beckage

讲授课程

研究生课程:数据分析与可视化(R)

本科生课程:C/C++程序设计,生态水文过程与模拟,陆地生态系统生态学,水文学原理

论著专利

近几年主要学术论文:

2026年:

  1. Xue, B., Tang G.*, Ren Z.K., Zeng L.W.i, Li X.B., Li Y.Q., Jiang N. (2026) Phyllosphere microbiome-physicochemical dynamics shape nitrogen resorption efficiency divergence during leaf senescence in subtropical forests of southern China. Forest Ecology and Management, 606, 123547: 1-11。
  2. Chen, H.B., Yu Y.B., Fang X.P., Jiang N., Xue B., Li Y., Tang G.* (2026) Carbon balance in an agriculture-disturbed forested headwater stream in South China: Variations and environmental controls. Journal of Environmental Management, 400, 128720: 1-13.

2025年:

  1. Li, X.B., Jiang N., Tang G.P.*, Zhang W.Y., Chen H.B., Xue B. (2025) Source, distribution and dynamics of dissolved inorganic carbon in a subtropical headwater catchment in Southern China. Journal of Hydrology: Regional Studies, 62, 102967: 1-13.
  2. Nan Jiang, Guoping Tang*, Wenya Zhang, Houbing Chen, Xupeng Fang, Zhongkai Ren, Xixi Lu bDistinguished behaviors between stream CO2 and CH4 concentrations and the potential causes in a headwater catchment of southern China. Journal of Hydrology, 662 (2025) 134055.1-13.
  3. Houbing Chen, Guoping Tang*, Nan Jiang, Zhongkai Ren, Xupeng Fang and Yaoliang Chen。Seasonal Dynamics, Environmental Drivers, and Hysteresis of Sap Flow in Forests of China’s Subtropical Transitional Zone。 Forests, 2025, 16, 1480.
  4. 李小彬,江南,唐国平*,崔国韬,高全洲. 粤北岩溶区小型流域水化学特征、组成及影响因素分析. 环境科学, 2025, https://doi.org/10.13227/j.hjkx.202411268

2024年:

  1. Wenya Zhang , Guoping Tang*, Xiaohua Chen , Yangbo Yu , Yi Li。Effects of changes in precipitation patterns and stream flow on stream DOC and NO- 3 concentrations in a headwater catchment in a subtropical region of southern China。Journal of Hydrology-Regional Studies, 2024,54 (2024) 101867.
  2. Tao Chen, Félicien Meunier, Marc Peaucelle, Guoping Tang*, Ye Yuan, and Hans Verbeeck. Elevated atmospheric CO2 concentration and vegetation structural changes contributed to gross primary productivity increase more than climate and forest cover changes in subtropical forests of China. Biogeosciences, 2024, 21, 2253–2272.
  3. 黎 毅,戴克元,唐国平,杜建会,陈 桃,江 南,牛香豫,余扬波。基于遥感生态指数的广东石门台国家级自然保护区生态环境质量评价。热带地理,2024,44(3):429-441.

2023年:

  1. Chen, T.; Tang, G.*; Yuan, Y.; Xu, Z.; Jiang, N. Disentangling the Key Drivers of Ecosystem Water-Use Efficiency in China’s Subtropical Forests Using an Improved Remote-Sensing-Driven Analytical Model. Remote Sensing. 202315, 2441. https://doi.org/10.3390/rs15092441.
  2. Ablat, X.; Huang, C.; Tang, G.*; Erkin, N.; Sawut, R. Modeling Soil CO2 Efflux in a Subtropical Forest by Combining Fused Remote Sensing Images with Linear Mixed Effect Models. Remote Sensing. 202315, 1415. https://doi.org/10.3390/rs15051415.
  3. Wang, Z., Zhang, Y., Govers, G., Tang, G., Quine, T.A., Qiu, J., Navas, A., Fang, H., Tan, Q., Van Oost, K. Temperature effect on erosion-induced disturbances to soil organic carbon cycling. Nature Climate Change, 2023, 13, 174–181. https://doi.org/10.1038/s41558-022-01562-8. 
  4. Muattar Saydi, Guoping Tang*, Jianli Ding, Zhengang Wang. Snow depth alteration and its relation with climate variability in China. International Journal of Climatology, 2023, 43, 2623-2646. https://doi.org/10.1002/joc.7993.
  5. 余洋波,唐国平*,等. 土地利用和气候变化对流溪河水库流域径流的影响. 水土保持研究. 2023,30(06): 32-39,48.
  6. Nan Jiang, Guoping Tang*, Tao Chen, Xiangyu Niu, Yangbo Yu, Yi Li, 2023. A global analysis on the relationship between water retention time and dissolved carbon across inland waters. Aquatic Sciences, 85(4), 1-12.

2022年:

  1. 牛香豫,唐国平*,顾慧,陈桃,陈晓桦.流溪河水库流域碳氮营养盐浓度的时空变化特征及其影响因素[J].水土保持学报,2022,36(02):352-360. DOI:10.13870/j.cnki.stbcxb.2022.02.045.
  2. Zhenwu Xu, Lin Sun, Guoping Tang*, Xiaohua Chen, Xiangyu Niu, Yi Li, and Yangbo Yu, 2022. Do model results vary under different routing algorithms based on a distributed ecohydrological model? Journal of Hydrometeorology, DOI: https://doi.org/10.1175/JHM-D-21-0251.1.
  3. Chen Xiaohua, Guoping Tang*, Tao Chen, Xiangyu Niu, 2022. An Assessment of the Impacts of Snowmelt Rate and Continuity Shifts on Streamflow Dynamics in Three Alpine Watersheds in the Western U.S. Water, 14(7):1095. DOI: 10.3390/w14071095
  4. Xarapat Ablat, Qi Wang, Nurmemet Arkin, Guoping Tang*, Rukeya Sawut, 2022. Spatiotemporal variations and underlying mechanism of the floodplain wetlands in the meandering Yellow River in arid and semi-arid regions. Ecological Indicators, 136: 108709, https://doi.org/10.1016/j.ecolind.2022.108709.

2021年:

  1. Tao Chen, Zhenwu Xu, Guoping Tang*; Xiaohua Chen, Hong Fang, Hao Guo, Ye Yuan, Guoxiong Zheng, Liangliang Jiang, Xiangyu Niu, (2021). Spatiotemporal Monitoring of Soil CO2 Efflux in a Subtropical Forest during the Dry Season Based on Field Observations and Remote Sensing Imagery. Remote Sensing. 13, 3481. https://doi.org/10.3390/rs13173481. (IF = 4.848)
  2. Zhenwu Xu, Guoping Tang*, Tao Jiang, Xiaohua Chen, Tao Chen, Xiangyu Niu, (2021). An automatic partition-based parallel algorithm for grid-based distributed hydrological models. Environmental Modelling and Software, 144(2021):105142(1-15). https://doi.org/10.1016/j.envsoft.2021.105142.(IF = 5.288)
  3. Muzhen Yang, Guoping Tang*, Jiang Tao, Tao Chen, Xiaohua Chen, (2021). The regular pattern and underlying mechanisms of seawater intrusion in the Modaomen channel in the Pearl River Estuary of China. Environmental Science and Pollution Research, 1-15. Https://doi.org/10.1007/s11356-021-14942-y.(IF = 4.223)
  4. Muattar Saydi, Guoping Tang*, Yan Qin, Hong Fang,  Xiaohua Chen, (2021). Evaluation of Phase discrimination methods and snow fraction perturbations in arid regions of northwest China. Journal of Hydrometeorology, 22(2): 353-369. https://doi.org/10.1175/JHM-D-20-0118.1. (IF = 4.349)
  5. Zhenhuan Liu, Qiandu Huang, Guoping Tang, (2021). Identification of urban flight corridors for migratory birds in the coastal regions of Shenzhen city based on three dimensional landscape. Landscape Ecology, 36: 2043-2057. https://doi.org/10.1007/s1090-020-010326. (IF = 3.848)

2020年:

  1. Guoping Tang*, Muzhen Yang, Xiahong Chen, Tao Jiang, Tao Chen, Xiaohua Chen, Hong Fang, (2020). A new idea for predicting and managing seawater intrusion in coastal channels of the pearl river, china. Journal of Hydrology,590, 125454:https://doi.org/10.1016/j.jhydrol.2020.125454. (IF = 5.722, 中科院一区 TOP)
  2. Tao Chen, Guoping Tang*, Ye Yuan, Hao Guo, Zhenwu Xu, Guo Jiang, Xiaohua Chen, (2020). Unraveling the relative impacts of climate change and human activities on grassland productivity in Central Asia over last three decades. Science of the Total Environment,743,140649:1-13. https://doi. org/10.1016/j.scitotenv.2020.140649. (IF = 7.963, 中科院一区 TOP)
  3. 顾慧, 唐国平*, 江涛. 模型驱动数据空间分辨率对模拟生态水文过程的影响[J]. 地理研究, 2020, 39(06): 1255-1268. (中科院T1区)
  4. 顾慧, 唐国平*, 江涛, 方宏, 唐纤蕴, 陈晓桦. 广东省1992-2015年土地覆被变化的时空差异及其成因[J]. 水土保持通报, 2020, 40(02): 291-298.

2015-2019年:

  1. Guoping Tang*, Shuping Li, Muzhen Yang, Zhenwu Xu, Yonglin Liu, Hui Gu. Streamflow response to climate variability-associated shifts in snow regime in four mountain watersheds in the US Great Basin. Journal of Hydrology,573(2019):255-266 (SCI, IF=3.727).
  2. Yuzhen Wu, Guoping Tang*, Hui Gu, Yongling Liu, Muzhen Yang, Lin Sun. The variation of vegetation greenness and underlying mechanisms in Guangdong province of China during 2001-2013 based on MODIS data. Science of the Total Environment. 2019, 653(2019), 536-546. DOI:10.1016/J.SCITOTENV.2018.10.380. (SCI, IF=4.610,2018)
  3. Yonging Liu, Guoping Tang*, Liqiao Wu, Yuzhen Wu, Muzhen Yang. Variations in reference evapotranspiration and associated driving forces in the Pearl River Delta of China during 1960-2016. Journal of the Meteorological Society of Japan. 2019, Inpress,DOI:10.2151/JMSJ.2019-027. (SCI, IF=5.023, 2018)
  4. 孙琳,唐国平,窦乙峰,刘永林,吴裕珍. 东江流域2001-2013年土地利用/覆被类型变化的时空特征及成因. 水土保持通报,2018,38(3):293-306.
  5. Tingting Xue, Guoping Tang*, Sun Lin, Wu Yuzhen, Liu Yonglin, Dou Yifeng. (2017). Long-term trends in precipitation and precipitation extremes and underlying mechanisms in the US Great Basin during 1951-2013. Journal of Geophysical Research--Atmosphere, 122, 6152-6169. doi: 10.1002/2017JD026682. (SCI, IF=3.318)
  6. Guoping Tang*, Rosemary W.H., Lutz A., and Sun L. (2016) Regulation of precipitation-associated vegetation dynamics on catchment water balance in a semiarid and arid mountainous watershed. Ecohydrology, 9, 1248-1262. (SCI, IF=2.426).
  7. Tang  G., Arnone III J.A., Verburg P.S.J., Jasoni R., and Sun L. (2015) Trend and climatic sensitivity of vegetation phenology in semiarid and arid ecosystems in the US Great Basin during 1982-2011. Biogeosciences,12,6985-6997. 2015. DOI:10.5194/BG-12-6985-2015, (SCI, IF=3.978).

2014年前:

  1. Tang G., Hwang T., and Pradhanang S.M. (2014) Does consideration of water routing affect simulated water and carbon dynamics in terrestrial ecosystems? Hydrology and Earth System Sciences, 18,1-15. DOI:10.5194/hess-18-1-2014. (SCI, IF=3.642).
  2. Tang G., Beckage B., and Smith B (2014) Potential future dynamics of carbon fluxes and pools in New England forests and their climatic sensitivities: a model-based study”. Global Biogeochemical Cycles, 28, 1-14. DOI:10.1002/2013GB004656. (SCI, IF=4.528).
  3. Tang G., and J. Arnone III (2013) Trends in surface air temperature and temperature extremes in the Great Basin during the 20th century from ground-based observations. Journal of Geophysical Research–Atmosphere,118,3579–3589, doi:10.1002/jgrd.50360, 2013. (SCI, IF=3.44).
  4. Tang  G., and Bartlein PJ (2012) Modifying a global dynamic vegetation model for simulating large-spatial scale land surface water balances.Hydrology and Earth System Sciences, 16, 2547-2565. (SCI, IF=3.642).
  5. Tang G., Beckage B, and Smith B (2012) The potential transient dynamics of forests in New England under historical and projected future climate change. Climatic Change, 114(2), 357-377. (SCI, IF=4.622).
  6. Tang G.,Beckage B, Smith B, and Miller PA (2010) Estimating potential forest NPP and biomass and their climatic sensitivity in New England using a regional dynamic ecosystem model. Ecosphere, 1(6), 1-20. (SCI, IF=2.595).
  7. Tang G., and Beckage B (2010) Projecting the distribution of forests in New England in response to climate change. Diversity and Distribution, 16, 144-158. (SCI, IF=5.469).
  8. Tang G., Shafer SL, Bartlein PJ, and Holman J. (2009) Effects of experimental protocol on the evaluation of global vegetation model accuracy: a comparison of simulated and observed vegetation patterns for Asia. Ecological Modelling, 220(2009), 1481-1491. (SCI, IF=2.326).
  9. Tang G., and Bartlein PJ (2008) Simulating the climatic effects on vegetation: approaches, issues and challenges. Progress in Physical Geography, 32(5), 543-556. (SCI, IF=3.885).
  10. Tang  G. (2008) A new metric for evaluating the correspondence of spatial patterns in vegetation models. Global Ecology and Biogeography,17, 465-478. (SCI, IF=7.242).
  11. 唐国平,李秀彬,Guenther Fischer, Sylvia Prieler. (2000) 气候变化对中国农业的影响. 地理学报,55(2):129-138.
  12. 唐国平,杨志峰.(2000)密云水库水环境人口容量优化分析.环境科学学报,20(2):225-229。
  13. 唐国平,李秀彬,刘燕华. (2000) 全球气候变化下水资源脆弱性及其评估方法.地球科学进展,15(3):313-317.

 

科研项目

  • 2023.01 - 2025.12:广东省科技厅2023 年度平台基地及科技基础条件建设项目“粤北岩溶区碳水耦合野外科学观测研究站” (直接经费: 300万元),项目负责人.
  • 2023.01 - 2025.12:广东省自然科学基金面上项目“河流生态流量精细化估算技术及应用” (NO: 2023A1515012069, 直接经费: 10万元),项目负责人.
  • 2022.01 - 2025.12:中国国家自然科学基金面上项目“华南湿热区河流源区土-气界面和水-气界面碳通量动态及联系机理” (No. 42171025,直接经费: 59万元),项目负责人.
  • 2017.07 - 2020.12:科技部“珠江流域水资源多目标调度技术与应用” 重点研发项目(负责人:陈晓宏)子课题《珠江三角洲咸潮上溯的水资源系统响应规律》(直接经费:27万),子课题负责人.
  • 2017.01 - 2018.12:中山大学重大项目和前沿新兴交叉学科培育资助项目“气候变化和人类活动对我国湿热地区陆地生态系统结构和碳通量的影响”(直接经费:30万元),项目负责人.
  • 2017.01 - 2019.12:广州市科技计划项目“分析陆地植被对流溪河径流和水体溶解有机氮浓度的调控”(直接经费:20万元),项目负责人.
  • 2017.01 - 2020.12:中国国家自然科学基金面上项目“气候变化与土地利用对东江流域河流碳氮营养物浓度的影响” (No. 41671192,直接经费: 70万元),项目负责人.
  • 2015.03 - 2017.07:中山大学第二期百人计划启动项目(直接经费:50万元),项目负责人.
  • 2014.07 - 2015.10:DRI Institute Project Assignment:“Improving a process-based hydro-ecological model for promoting collaborative research and fund raising of faculties at the DRI”。负责人,$9,978.
  • 2014.02 - 2015.2: 美国内华达Lander Endowment Project:“Effects of climate change and variability on the Walker River hydrology and their implications for Native Americans in the Walker River Indian Reservation”。负责人,$30,200.
  • 2013.09 - 2014.09:美国内政部项目:“Linking climatic, hydrological, and ecological changes at intermediate timescales in a Great Basin watershed”。共同负责人,$187,432.
  • 2011.09 - 2013.10:美国国家自然科学基金项目(NSF‐EPSCoR):“NevadaInfrastructure for Climate Change Science, Education and Outreach”,项目参与者。 负责人: Dr. Gayle L. Dana.

其他

学术组织会员

中国地理学会、美国地球物理协会,美国生态协会,美国地理协会