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Plant Plant Interactions in Elevated CO2 Environments
FA Bazzaz and KDM McConnaughay
40(5) pp.547 - 563
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Traw M. B.,
Lindroth R. L., Bazzaz F. A.
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Photosynthesis and the Environment (2004)
Conservation Biology (1998)
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Wayne P. M.,
Carnelli A. L.,
Connolly J., Bazzaz F. A.
Journal of Ecology. 1999 87(2). p.183
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Navas M.‐L.
Functional Ecology. 1998 12(5). p.721
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Wieneke Silvia,
Prati Daniel,
Brandl Roland,
Stöcklin Jürg, Auge Harald
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Joel Geeske,
Chapin F. Stuart,
Chiariello Nona R.,
Thayer Susan S., Field Christopher B.
Global Change Biology. 2001 7(4). p.435
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Kubiske M. E.,
Quinn V. S.,
Marquardt P. E., Karnosky D. F.
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Dijkstra Feike A.,
Blumenthal Dana,
Morgan Jack A.,
LeCain Daniel R., Follett Ronald F.
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Cotrufo M Francesca,
Berg Björn, Kratz Werner
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Grams Thorsten E.E.,
Matyssek Rainer, Rennenberg Heinz
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Edwards G. R.,
Newton P. C. D.,
Tilbrook J. C., Clark H.
New Phytologist. 2001 150(2). p.359
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Wand Stephanie J. E.,
Midgley Guy F., Musil Charles F.
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Friedlingstein P.,
Joel G.,
Field C. B., Fung I. Y.
Global Change Biology. 1999 5(7). p.755
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Comins Hugh N.
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Ackerly David D.,
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Cantin D,
Tremblay M F,
Lechowicz M J, Potvin C
Canadian Journal of Forest Research. 1997 27(4). p.510
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Kruger E. L.,
Riemenschneider D. E., Isebrands J. G.
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Wang X.,
Ngigi A. R.,
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Heuer M.L.,
Hunsaker D.,
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Oecologia. 2007 152(4). p.595
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Dugas W. A.,
Johnson H. B.,
Polley H. W., Sanabria J.
Global Change Biology. 2001 7(7). p.747
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Sulzman Elizabeth W.,
Poiani Karen A., Kittel Timothy G. F.
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van Loon Marloes P.,
Rietkerk Max,
Dekker Stefan C.,
Hikosaka Kouki,
Ueda Miki U., Anten Niels P. R.
Annals of Botany. 2016 117(7). p.1197
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Polley H. Wayne,
Johnson Hyrum B., Derner Justin D.
New Phytologist. 2003 160(2). p.319
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Journal of Crop Improvement. 2005 13(1-2). p.73
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Ziska Lewis H.,
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Teyssonneyre F.,
Picon‐Cochard C., Soussana J. F.
New Phytologist. 2002 154(1). p.53
Inter- and intra-generic differences in growth, reproduction, and fitness of nine herbaceous annual species grown in elevated CO2 environments
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Oecologia. 1995 104(4). p.454
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Harmens H.,
Williams P. D.,
Peters S. L.,
Bambrick M. T.,
Hopkins A., Ashenden T. W.
Grass and Forage Science. 2004 59(2). p.144
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Davis M. A.,
Pritchard S. G.,
Prior S. A.,
Mitchell R. J.,
Torbert H. A.,
Rogers H. H., Dute R. R.
Journal of Environmental Quality. 2006 35(4). p.1478
Elevated atmospheric CO2 and species mixture alter N acquisition of trees in stand microcosms
Friend Alexander L,
Jifon John L,
Berrang Paul C,
Seiler John R, Mobley Juanita A
Canadian Journal of Forest Research. 2000 30(5). p.827
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Norby Richard J.
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Carbon Dioxide, Populations, and Communities (1996)
Towards a better experimental basis for upscaling plant responses to elevated CO2 and climate warming
KÖRNER Ch.
Plant, Cell & Environment. 1995 18(10). p.1101
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Qiao Yun‐Zhou,
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Wang Qian, Tian Qi‐Zhuo
Journal of Integrative Plant Biology. 2008 50(3). p.265
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Rämö Kaisa,
Kanerva Teri,
Nikula Suvi,
Ojanperä Katinka, Manninen Sirkku
Environmental Pollution. 2006 144(1). p.101
Virus‐induced differences in the response of oat plants to elevated carbon dioxide
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Plant, Cell & Environment. 1997 20(2). p.178
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Carbon Dioxide and Terrestrial Ecosystems (1996)
The response of perennial ryegrass/white clover swards to elevated atmospheric CO2concentrations 1. Effects on competition and species composition and interaction with N supply
SCHENK U.,
JÄGER H.‐J., WEIGEL H.‐J.
New Phytologist. 1997 135(1). p.67
Elevated carbon dioxide is predicted to promote coexistence among competing species in a trait‐based model
Ali Ashehad A.,
Medlyn Belinda E.,
Aubier Thomas G.,
Crous Kristine Y., Reich Peter B.
Ecology and Evolution. 2015 5(20). p.4717
