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Assimilation, Stomatal Conductance, Specific Leaf Area and Chlorophyll Responses to Elevated CO2 of Maranthes corymbosa, a Tropical Monsoon Rain Forest Species
D Eamus, CA Berryman and GA Duff
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The role of temperature in determining the stimulation of CO2 assimilation at elevated carbon dioxide concentration in soybean seedlings
Ziska Lewis H., Bunce James A.
Physiologia Plantarum. 1997 100(1). p.126
13C discrimination by fossil leaves during the late-glacial climate oscillation 12-10 ka BP: measurements and physiological controls
Beerling D. J.
Oecologia. 1996 108(1). p.29
Increased drought and atmospheric CO2 positively impact intrinsic water use efficiency but do not promote tree growth in semi-arid areas of northwestern China
Lu Kanglong,
Chen Ning,
Zhang Xiaowei,
Wang Jingru,
Wang Minghao,
Khan Salman,
Han Chun,
Zhang Cankun,
Wang Shuyuan,
Wang Luning,
Gao Wenting,
Liu Yongjing, Zhao Changming
Trees. 2019 33(3). p.669
CO2 assimilation rate of canopy leaves in rain forest trees: high or low?
OGINO Kazuhiko, FURUKAWA Akio
Tropics. 1995 4(4). p.287
The Productivity and Sustainability of Southern Forest Ecosystems in a Changing Environment (1998)
Seasonal and diurnal photosynthetic responses of two gerbera cultivars to different substrates and heating systems
Issa Mohamad,
Ouzounidou Georgia,
Maloupa Helen, Constantinidou Helen-Isis A
Scientia Horticulturae. 2001 88(3). p.215
Response of maize (Zea mays L.) on yield, physiology and stomatal behaviour under two different elevated CO2 concentrations. Do these anatomical changes affect the physiology of the C4 crop plant under high CO2 conditions?
Ira Khan,
Maddi Vanaja,
Poldasari Sathish,
Mohammad Faizan,
Sipan Soysal,
Rajput Vishnu D.,
Ivica Djalovic,
Goran Trivan, Pravej Alam
Plant, Soil and Environment. 2024 70(10). p.601
Tansley Review No. 71 Effects of elevated atmospheric CO2on woody plants
CEULEMANS REINHART, MOUSSEAU MARIANNE
New Phytologist. 1994 127(3). p.425
The interaction of high temperature and elevated CO2 on photosynthetic acclimation of single leaves of rice in situ
Lin Weihong,
Ziska Lewis H.,
Namuco Offilia S., Bai Kezhi
Physiologia Plantarum. 1997 99(1). p.178
Photosynthesis and biomass accumulation in Carapa surinamensis (Meliaceae) in response to water stress at ambient and elevated CO2
OLIVEIRA M.F., MARENCO R.A.
Photosynthetica. 2019 57(1). p.137
Handbook of Plant and Crop Stress, Second Edition (1999)
Transpiration and stomatal resistance variations of perennial tropical crops under soil water availability conditions and water deficit
Sena José Ozinaldo Alves de,
Zaidan Humberto Actis, Castro Paulo Roberto de Camargo e
Brazilian Archives of Biology and Technology. 2007 50(2). p.225
New insights into the covariation of stomatal, mesophyll and hydraulic conductances from optimization models incorporating nonstomatal limitations to photosynthesis
Dewar Roderick,
Mauranen Aleksanteri,
Mäkelä Annikki,
Hölttä Teemu,
Medlyn Belinda, Vesala Timo
New Phytologist. 2018 217(2). p.571
Photosynthetic responses to temperature, light flux-density, CO2 concentration and vapour pressure deficit in Eucalyptus tetrodonta grown under CO2 enrichment
Eamus Derek,
Duff G.A., Berryman C.A.
Environmental Pollution. 1995 90(1). p.41
Long-term changes in the tree radial growth and intrinsic water-use efficiency of Chuanxi spruce (Picea likiangensis var. balfouriana) in southwestern China
Wang Yang,
Zhang Yong,
Fang Ouya, Shao Xuemei
Journal of Geographical Sciences. 2018 28(6). p.833
Growth and yield responses of wheat plants to elevated levels of CO2 and SO2, singly and in combination
Deepak S.S, Agrawal Madhoolika
Environmental Pollution. 1999 104(3). p.411
Stomatal density and stomatal index as indicators of paleoatmospheric CO2 concentration
Royer D.L.
Review of Palaeobotany and Palynology. 2001 114(1-2). p.1
Stomatal sensitivity to CO2 diverges between angiosperm and gymnosperm tree species
Klein Tamir,
Ramon Uria, McCulloh Katherine
Functional Ecology. 2019 33(8). p.1411
Stomatal conductance of forest species after long‐term exposure to elevated CO2 concentration: a synthesis
Medlyn B. E.,
Barton C. V. M.,
Broadmeadow M. S. J.,
Ceulemans R.,
De Angelis P.,
Forstreuter M.,
Freeman M.,
Jackson S. B.,
Kellomäki S.,
Laitat E.,
Rey A.,
Roberntz P.,
Sigurdsson B. D.,
Strassemeyer J.,
Wang K.,
Curtis P. S., Jarvis P. G.
New Phytologist. 2001 149(2). p.247
Plant Ecophysiology and Adaptation under Climate Change: Mechanisms and Perspectives I (2020)
A meta‐analysis of responses of C3 plants to atmospheric CO2: dose–response curves for 85 traits ranging from the molecular to the whole‐plant level
Poorter Hendrik,
Knopf Oliver,
Wright Ian J.,
Temme Andries A.,
Hogewoning Sander W.,
Graf Alexander,
Cernusak Lucas A., Pons Thijs L.
New Phytologist. 2022 233(4). p.1560
Cladode development forOpuntia ficus‐indica (Cactaceae) under current and doubled CO2concentrations
North Gretchen B.,
Moore T. Lin, Nobel Park S.
American Journal of Botany. 1995 82(2). p.159
Smoke-haze from the 1997 Indonesian forest fires: effects on pollution levels, local climate, atmospheric CO2 concentrations, and tree photosynthesis
Davies Stuart J., Unam Layang
Forest Ecology and Management. 1999 124(2-3). p.137
Stomatal responses to increased CO2: implications from the plant to the global scale
FIELD C. B.,
JACKSON R. B., MOONEY H. A.
Plant, Cell & Environment. 1995 18(10). p.1214
The influence of CO2concentration on stomatal density
WOODWARD F. I., KELLY C. K.
New Phytologist. 1995 131(3). p.311
Tropical forest responses to increasing atmospheric CO2: current knowledge and opportunities for future research
Cernusak Lucas A.,
Winter Klaus,
Dalling James W.,
Holtum Joseph A. M.,
Jaramillo Carlos,
Körner Christian,
Leakey Andrew D. B.,
Norby Richard J.,
Poulter Benjamin,
Turner Benjamin L., Wright S. Joseph
Functional Plant Biology. 2013 40(6). p.531
Increased intrinsic water-use efficiency during a period with persistent decreased tree radial growth in northwestern China: Causes and implications
Wang Wenzhi,
Liu Xiaohong,
An Wenling,
Xu Guobao, Zeng Xiaomin
Forest Ecology and Management. 2012 275 p.14
Canopy quantum yield in a mesocosm study
Luo Yiqi,
Hui Dafeng,
Cheng Weixin,
Coleman James S.,
Johnson Dale W., Sims Daniel A.
Agricultural and Forest Meteorology. 2000 100(1). p.35
Photosynthetic response of Cannabis sativa L., an important medicinal plant, to elevated levels of CO2
Chandra Suman,
Lata Hemant,
Khan Ikhlas A., ElSohly Mahmoud A.
Physiology and Molecular Biology of Plants. 2011 17(3). p.291
MORE EFFICIENT PLANTS: A Consequence of Rising Atmospheric CO2?
Drake Bert G.,
Gonzàlez-Meler Miquel A., Long Steve P.
Annual Review of Plant Physiology and Plant Molecular Biology. 1997 48(1). p.609
A meta‐analysis of leaf gas exchange and nitrogen in trees grown under elevated carbon dioxide
CURTIS P. S.
Plant, Cell & Environment. 1996 19(2). p.127
