Ge Zhenming

Job Title: 
Professor
Research Interests: 
Climate Change & Ecosystem Carbon/water process
Ecological Model
Wetland Ecology
Email: 
zmge@sklec.ecnu.edu.cn
Address: 
Zhongshan N. Road 3663,Shanghai 200062, China
Education Experience: 
2011 Ph.D.(GrantedU-S-L),University of Eastern Finland
2007 Ph.D.,East China Normal University
Work Experience: 
2012- Associate Professor,State Key Laboratory of Estuarine and Coastal Research, East China Normal University
2010-2011 Senior Researcher, University of Eastern Finland, Center of Excellence(AF)
2008-2010 Postdoctoral Fellow,University of Eastern Finland
2007-2008 Lecturer, East China Normal University
Paper: 
(1) Selected Refereed Articles
[1]  Ge, Z.M.*, Cao, H.B, Cui, L.F., Zhao, B., Zhang, L.Q. 2015. Future vegetation patterns and primary production in the coastal wetlands of East China under sea level rise, sediment reduction and saltwater intrusion. Journal of Geophysical Research - Biogeosciences, 120, 1923-1940.
[2]  Ge, Z.M.*, Guo, H.Q., Zhao, B., Zhang, L.Q., 2015. Plant invasion impacts on the gross and net primary production of the salt marsh on eastern coast of China: insights from leaf to ecosystem. Journal of Geophysical Research - Biogeosciences, 120, 169–186.
[3]  Ge, Z.M.*, Zhang, L.Q., Yuan, L. 2015. Spatiotemporal dynamics of salt marsh vegetation regulated by plant invasion and abiotic processes in the Yangtze Estuary: observations with a modeling approach. Estuaries and Coasts, 38, 310–324.
[4]  Ge, Z.M.*, Zhang, L.Q., Yuan, L., Zhang, C. 2014. Effects of salinity on temperature-dependent photosynthetic parameters of a native C3 and a non-native C4 marsh grass in the Yangtze Estuary, China. Photosynthetica, 52, 484–492.
[5]  Ge, Z.M., Cao, H.B., Zhang, L.Q. 2013. A process-based grid model for range expansion of Spartina alterniflora on the coastal saltmarshes in the Yangtze Estuary. Ecological Engineering, 58, 105–112.
[6]  Ge, Z.M.*, Kellomaki, S., Peltola, H., Zhou, X., Vaisanen, H. 2013. Impacts of climate change on primary production and carbon sequestration of boreal Norway spruce forests: Finland as a model. Climatic Change, 118, 259–273.
[7]  Ge, Z.M.*, Kellomaki, S., Peltola, H., Zhou, X., Vaisanen, H. 2013. Adaptive management to climate change for Norway spruce forests along a regional gradient in Finland. Climatic Change, 118, 275–289.
[8]  Ge, Z.M.*, Kellomaki, S., Zhou, X., Wang, K.Y., Peltola, H. 2011. Evaluation of carbon exchange in a boreal coniferous stand over a 10-year period: an integrated analysis based on ecosystem model simulations and eddy covariance measurements. Agricultural and Forest Meteorology, 151, 191–203.
[9]  Ge, Z.M.*, Zhou, X., Kellomaki, S., Peltola, H., Wang, K.Y. 2012. Measured and modeled biomass growth in relation to photosynthesis acclimation of Reed canary grass under elevated temperature, CO2 enrichment and different water regimes. Biomass & Bioenergy, 46, 251–262.
[10] Ge, Z.M.*, Zhou, X., Biasi, C., Kellomaki, S., Peltola, H., Martikainen, P.J. 2012. Carbon assimilation and allocation (13C labeling) in a boreal perennial grass (Phalaris arundinacea) subjected to elevated temperature and CO2 through a growing season. Environmental and Experimental Botany, 75, 150–158.
[11] Ge, Z.M.*, Kellomaki, S., Zhou, X., Peltola, H. 2014. The role of climatic variability in controlling carbon and water budgets in a boreal Scots pine forest during ten growing seasons. Boreal Environment Research, 19, 181–194.
[12] Ge, Z.M.*, Kellomaki, S., Peltola, H., Zhou, X., Wang, K.Y. 2011. Impacts of changing climate on the productivity of Norway spruce dominant mix-stands with Scots pine and birch in relation to the water availability in southern and northern Finland. Tree Physiology, 31, 323–338.(Cover story)
[13] Ge, Z.M.*, Kellomaki, S., Peltola, H., Zhou, X., Wang, K.Y. 2013. Effects of climate change on the evapotranspiration and water availability in the boreal forests located in Southern Finland: an ecosystem model based approach. Ecohydrology, 6, 51–63.
[14] Ge, Z.M.*, Zhou, X., Kellomaki, S., Peltola, H., Wang, K.Y. 2011. Climate, canopy conductance and leaf area development controls on evapotranspiration and its components in a boreal coniferous stand over a 10 year period: a united assessment based on hydrological model with forest growth model. Ecological Modelling, 222, 1626–1638.
[15] Ge, Z.M.*, Zhou, X., Kellomaki, S., Wang, K.Y., Peltola, H. 2010. Effects of changing climate on water and nitrogen availability with implications on the productivity of Norway spruce stands in southern Finland. Ecological Modelling, 221, 1731–1743.
[16] Ge, Z.M.*, Kellomaki, S., Peltola, H., Zhou, X., Wang, K.Y. 2011. Effects of varying thinning regimes on carbon uptake, total stem wood growth, and timber production in Norway spruce (Picea abies) stands in southern Finland under the changing climate. Annals of Forest Science, 68, 371–383.
[17] Ge, Z.M.*, Zhou, X., Kellomaki, S., Wang, K.Y., Peltola, H., Martikainen, P.J. 2012. Seasonal physiological responses and biomass growth in a bioenergy crop (Phalaris arundinacea L.) under elevated temperature and CO2, subjected to different water regimes in boreal conditions. BioEnergy Research, 5, 637–648.
[18] Ge, Z.M.*, Zhou, X., Kellomaki, S., Zhang, C., Peltola, H., Martikainen, P.J. 2012. Acclimation of photosynthesis in a boreal grass (Phalaris arundinacea L.) under different temperature, CO2 and soil water regimes. Photosynthetica, 50,141–151.
[19] Ge, Z.M.*, Zhou, X., Kellomaki, S., Wang, K.Y., Peltola, H., Martikainen, P.J. 2011. Responses of leaf photosynthesis, pigments and chlorophyll fluorescence within canopy position in a boreal grass (Phalaris arundinacea L.) to elevated temperature and CO2 under varying water regimes. Photosynthetica, 49, 172–184.
[20] Ge, Z.M.*, Zhou, X., et al. 2009. The effects of changes in vegetation cover on the migratory shorebird carrying capacity of a newly-formed wetland, Yangtze River Estuary, China. Zoological studies 48, 769–779.
[21] Ge, Z.M., Wang, T., et al. 2007. Changes in the spatial distribution of migratory shorebirds along the Shanghai shoreline, China, between 1984 and 2004. Emu 107, 19–27.
[22] Ge, Z.M., Wang, T., et al. 2006. Use of wetlands at the mouth of the Yangtze River by shorebirds during spring and fall migration. Journal of Field Ornithology 77, 347–356.
[23] Hu, Z.J., Ge, Z.M.*, Ma, Q., Zhang, Z.T., Tang, C.D., Cao, H.B., Zhang, T.Y., Li, B., Zhang, L.Q., 2015. Revegetation of a native species in a newly formed tidal marsh under varying hydrological conditions and planting densities in the Yangtze Estuary. Ecological Engineering, 83, 354–363.
[24] Wang, H., Ge, Z.M.*, Yuan, L., Zhang, L.Q.*, 2014. Evaluation of the combined risk of sea-level rise and sedimentation reduction on the coastal wetlands in the Yangtze Estuary, China. Ecological Engineering, 71, 346–354.
[25] Cui, L.F., Ge, Z.M.*, Yuan, L., Zhang, L.Q.*, 2014. Vulnerability assessment of the coastal wetlands in the Yangtze Estuary, China to sea-level rise. Estuarine, Coastal and Shelf Science, 156, 42–51.
[26] Zhou, X.*, Ge, Z.M., Kellomaki, S., Wang, K.Y., Peltola, H., Shurpali, N., Martikainen, P.J. 2011. Effects of elevated CO2 and temperature on leaf characteristics, photosynthesis and carbon storage in aboveground biomass of a boreal bioenergy crop (Phalaris arundinacea L.) under varying water regimes. Global Change Biology Bioenergy, 3, 223–234.
[27] Zhang, C.*, Ge, Z.M., Kellomaki, S., Wang, K.Y., Zhou, X. 2013. Effects of elevated CO2 and temperature on biomass growth and allocation in a boreal bioenergy crop (Phalaris arundinacea L.) from young and old cultivations. BioEnergy Research, 6, 651–662.
[28] Zhou, X.*, Ge, Z.M., Kellomaki, S., Wang, K.Y., Peltola, H., Martikainen, P.J. 2012. Multi-objective environment chamber system for studying plant responses to climate change. Photosynthetica, 50, 24–34.
[29] Li, S.S., Meng, X.W., Ge, Z.M., Zhang, L.Q., 2015. Vulnerability assessment of the coastal mangrove ecosystems in Guangxi, China, to sea-level rise.Regional Environmental Change, 15, 265–275.
[30] Li, S.S., Meng, X.W., Ge, Z.M., Zhang, L.Q., 2015. Evaluation of the threat from sea-level rise to the mangrove ecosystems in Tieshangang Bay, southern China. Ocean & Coastal Management, 109, 1–8.
[31] Zhang, C.*, Kellomaki, S., Wang, K.Y., Zhou, X., Ge, Z.M., Strandman, H. 2013. Impacts of elevated temperature and CO2 with varying groundwater levels on seasonality of height and biomass growth of a boreal bioenergy crop (Phalaris arundinacea) – a modeling study. Botany, 91, 260–272.
[32] Ge, Z.M.*, Zhou, X., Shi, W.Y., et al. 2008. Carrying capacity for shorebirds during migratory seasons at the Jiuduansha Wetland, Yangtze River Estuary, China. Frontiers of Biology in China 3: 536–542.
[33] Ge, Z.M.*, Zhou, X., Shi, W.Y., et al. 2006. Seasonal change and ha Carrying capacity for shorebirds during migratory seasons at the Jiuduansha Wetland, Yangtze River Estuary, China.bitat selection of shorebird community at the South Yangtze River Mouth and North Hangzhou Bay, China. Acta Ecologica Sinica (Elsevier V.) 26: 40–47.
[34] 张天雨, 葛振鸣, 张利权, 严 格, 陈怀璞. 2015. 崇明东滩湿地植被类型和沉积特征对土壤碳、氮分布的影响. 环境科学学报, 35(3): 836–843.
[35] 严 格, 葛振鸣, 张利权. 2014. 崇明东滩湿地不同盐沼植物群落土壤碳储量分布. 应用生态学报, 25(1): 85–91.
[36] 曹浩斌, 葛振鸣, 张利权. 2014. 崇明东滩盐沼植被扩散格局及其形成机制研究. 生态学报, 34(14): 3944–3952.
[37] 崔利芳, 王 宁, 葛振鸣, 张利权. 2014. 海平面上升影响下长江口滨海湿地脆弱性评价. 应用生态学报, 25(2): 553–561.
[38] 李莎莎, 孟宪伟, 葛振鸣, 张利权. 2014. 海平面上升影响下广西钦州湾红树林脆弱性评价. 生态学报, 34(10): 2702–2711.
[39] 葛振鸣*, 周 晓, 王开运, Seppo Kellomaki. 2010. 长江河口典型湿地碳库动态研究方法. 生态学报, 30(4): 1097–1108.
[40] 葛振鸣*, 周 晓, 王小明, 等. 2006. 基于GIS的上海世博会游人分布和流动预测分析. 城市环境与城市生态, 19(6): 26–28.
[41] 葛振鸣*, 周 晓, 王开运, 等. 2009. 受损湖泊湿地生态修复规划与效益分析—以上海西郊湿地为例. 生态经济, 4: 30–36.
[42] 葛振鸣*, 周 晓, 肖 风, 等. 2008. 生态型港口综合评价指标体系初探—以上海港为例. 长江流域资源与环境, 3: 339–345.
[43] 葛振鸣, 王天厚, 施文彧, 等. 2005. 崇明东滩围垦堤内植被快速次生演替特征. 应用生态学报, 16(9): 1677–1681.
[44] 葛振鸣, 周 晓, 施文彧, 等. 2007. 九段沙湿地鸻形目鸟类迁徙季节环境容纳量. 生态学报, 27(1): 90-96.
[45] 葛振鸣, 王天厚, 施文彧, 周 晓. 2006. 长江口杭州湾鸻形目鸟类群落季节变化和生境选择. 生态学报, 26(1): 40-47.
[46] Ge, Z.M., Wang, T.H., Shi, W.Y., et al., 2005. Impacts of environmental factors on the avian community in Shanghai woodlots in spring. Zoological Research‚ 26(1): 17-24. (In English)
[47] 葛振鸣, 王天厚, 周 晓 等. 2006. 上海崇明东滩堤内次生人工湿地鸟类冬春季生境选择的因子分析. 动物学研究, 27(2): 144-150.
[48] 施文彧, 葛振鸣, 周 晓, 等. 2007. 九段沙湿地植被群落演替与格局变化趋势. 生态学杂志, 26(2): 165–170.
[49] 赵 平, 葛振鸣, 王天厚, 等. 2005. 上海崇明东滩芦苇的生态特征及其演替过程的分析. 华东师范大学学报 (自然科学版), 3: 98–102.
[50] 周 晓, 葛振鸣, 施文彧, 等. 2006. 长江口九段沙湿地大型底栖动物群落结构的季节变化规律. 应用生态学报, 17(11): 2079–2083.
[51] 周 晓, 王天厚, 葛振鸣, 等. 2006. 长江口九段沙湿地不同生境中大型底栖动物群落结构特征分析. 生物多样性, 14(2): 165–171.
[52] 周 晓, 葛振鸣, 施文彧, 等. 2007. 长江口新生湿地大型底栖动物群落时空变化格局. 生态学杂志, 26(3): 372–377.
(2) Book chapters
[1] Editor in chief: 2008.《The ecological characteristics of the coastal wetland of Yangtze River estuary and the conservation strategy on the key wetland species》, Beijing: Science Press (ISBN 978-7-03-023124-6)
[2] Subeditor:2007.《The theory and practice of function restoration and structure reconstruction in the Xijiao lake wetland of Shanghai》, Beijing: Science Press (ISBN 978-7-03-019854-9)
Participant:
[1] 2011.《Development and application of spatial decision support system based on ecological carrying capacity – Chongming Island (Shanghai) as a case》, Beijing: Science Press (ISBN: 978-7-03-030984-6)
[2] 2008.《The research on functioning zones planning for 2010 Shanghai Expo》, Beijing: Science Press (ISBN: 978-7-03-021800-1)
[3] 2008.《The study of urban ecological elements and the construction of digital database – 2010 Expo area as an example》, Beijing: Science Press (ISBN: 978-7-03-022349-4)
Given papers in international conference:
[1] Ge, Z.M., Cao, H.B., Zhang, L.Q. 2013. Modeling the Dynamics of Coastal Saltmarsh Vegetation in the Yangtze Estuary: Invasion, Disturbance and Competition. In: ECSA-53, Estuaries and coastal areas in times of intense change conference. Shanghai, China
[2] Ge, Z.M., Zhang, L.Q. 2012. Impacts of Climate Change and Human Activities on Carbon Budget in Coastal Wetland Ecosystem. In: International Symposium on Climate change and human activities: Coastal Consequences and Responses. Shanghai, China. 28th–31s
[3] Ge, Z.M., 2012. Modeling Assessment and Sustainable Management of Carbon Sink/Source in Finnish Forests and Peatlands under Expected Climate Change. In: 9th Annual USCCC (US-China Carbon Consortium) Meeting. Changsha, China. 15th–18th June.
[4] Ge, Z.M., Zhou, X., 2008. The Theory and Practice of Function Restoration and Structure Reconstruction in the Disturbed Lake Wetland - Xijiao Wetland (Shanghai) as An Example. In: The symposiums of International Conference of Wetland Restoration. Nanjing