Effects of elevated atmospheric CO₂ on protozoan abundance in soil planted with wheat and on decomposition of wheat rootsRØNN, Regin; EKELUND, Flemming; CHRISTENSEN, Siren et al.Plant and soil. 2003, Vol 251, Num 1, pp 13-21, issn 0032-079X, 9 p.Article

The influence of plant species, fertilization and elevated CO₂ on soil aggregate stabilityEVINER, Valerie T; CHAPIN, F. Stuart.Plant and soil. 2002, Vol 246, Num 2, pp 211-219, issn 0032-079X, 9 p.Article

Individual vs. population plastic responses to elevated CO₂, nutrient availability, and heterogeneity : a microcosm experiment with co-occurring speciesMAESTRE, Fernando T; QUERO, José L; VALLADARES, Fernando et al.Plant and soil. 2007, Vol 296, Num 1-2, pp 53-64, issn 0032-079X, 12 p.Article

Responses of rice and winter wheat to free-air CO₂ enrichment (China FACE) at rice/wheat rotation systemHONGLIANG MA; JIANGUO ZHU; ZUBIN XIE et al.Plant and soil. 2007, Vol 294, Num 1-2, pp 137-146, issn 0032-079X, 10 p.Article

Competition for nitrogen between Pinus sylvestris and ectomycorrhizal fungi generates potential for negative feedback under elevated CO₂ALBERTON, Odair; KUYPER, Thomas W; GORISSEN, Antonie et al.Plant and soil. 2007, Vol 296, Num 1-2, pp 159-172, issn 0032-079X, 14 p.Article

Elevated CO₂ alleviates the effects of low P on the growth of N₂-fixing Acacia auriculiformis and Acacia mangiumNGUYEN, Nguyen Tran; PRAVAT KUMAR MOHAPATRA; FUJITA, Kounosuke et al.Plant and soil. 2006, Vol 285, Num 1-2, pp 369-379, issn 0032-079X, 11 p.Article

Progressive N limitation of plant response to elevated CO₂: a microbiological perspective : Role of microbial communities in mediating ecosystem response to disturbanceSHUIJIN HU; CONG TU; XIN CHEN et al.Plant and soil. 2006, Vol 289, Num 1-2, pp 47-58, issn 0032-079X, 12 p.Conference Paper

Elevated CO₂ does not favor a fungal decomposition pathwayVAN GROENIGEN, Kees-Jan; SIX, Johan; HARRIS, David et al.Soil biology & biochemistry. 2007, Vol 39, Num 8, pp 2168-2172, issn 0038-0717, 5 p.Article

Antioxidant capacity reduced in scallions grown under elevated CO₂ independent of assayed light intensityLEVINE, Lanfang H; PARE, Paul W.Advances in space research. 2009, Vol 44, Num 8, pp 887-894, issn 0273-1177, 8 p.Article

Long term CO₂ enrichment stimulates N-mineralisation and enzyme activities in calcareous grasslandEBERSBERGER, Diana; NIKLAUS, Pascal A; KANDELER, Ellen et al.Soil biology & biochemistry. 2003, Vol 35, Num 7, pp 965-972, issn 0038-0717, 8 p.Article

Elevated CO₂ response of photosynthesis depends on ozone concentration in aspenNOORMETS, Asko; KULL, Olevi; SOBER, Anu et al.Environmental pollution (1987). 2010, Vol 158, Num 4, pp 992-999, issn 0269-7491, 8 p.Conference Paper

Phenotypic and genetic differences in a perennial herb across a natural gradient of CO₂ concentrationNAKAMURA, Ito; ONODA, Yusuke; MATSUSHIMA, Noe et al.Oecologia. 2011, Vol 165, Num 3, pp 809-818, issn 0029-8549, 10 p.Article

Mycorrhizal and rhizomorph dynamics in a loblolly pine forest during 5 years of free-air-CO₂-enrichmentPRITCHARD, S. G; STRAND, A. E; MCCORMACK, M. L et al.Global change biology (Print). 2008, Vol 14, Num 6, pp 1252-1264, issn 1354-1013, 13 p.Article

Progressive nitrogen limitation of ecosystem processes under elevated CO₂ in a warm-temperate forest : Progressive nitrogen limitationFINZI, Adrien C; MOORE, David J. P; PIPPEN, Jeffrey S et al.Ecology (Durham). 2006, Vol 87, Num 1, pp 15-25, issn 0012-9658, 11 p.Article

Carbon sequestration in temperate grassland ecosystems and the influence of management, climate and elevated CO₂JONES, M. B; DONNELLY, Alison.New phytologist. 2004, Vol 164, Num 3, pp 423-439, issn 0028-646X, 17 p.Article

Development of C₄ photosynthesis in sorghum leaves grown under free-air CO₂ enrichment (FACE)COUSINS, A. B; ADAM, N. R; WALL, G. W et al.Journal of experimental botany. 2003, Vol 54, Num 389, pp 1969-1975, issn 0022-0957, 7 p.Article

Atmospheric CO₂ and O₃ alter competition for soil nitrogen in developing forestsZAK, Donald R; KUBISKE, Mark E; PREGITZER, Kurt S et al.Global change biology (Print). 2012, Vol 18, Num 4, pp 1480-1488, issn 1354-1013, 9 p.Article

Isoprene emissions from plants are mediated by atmospheric CO₂ concentrationsPOSSELL, Malcolm; NICHOLAS HEWITT, C.Global change biology (Print). 2011, Vol 17, Num 4, pp 1595-1610, issn 1354-1013, 16 p.Article

Curiosity and context revisited : crassulacean acid metabolism in the AnthropoceneOSMOND, Barry; NEALES, Tom; STANGE, Gert et al.Journal of experimental botany. 2008, Vol 59, Num 7, pp 1489-1502, issn 0022-0957, 14 p.Article

Taking mycocentrism seriously: mycorrhizal fungal and plant responses to elevated CO₂. CommentaryALBERTON, Odair; KUYPER, Thomas W; GORISSEN, Antonie et al.New phytologist. 2005, Vol 167, Num 3, pp 859-868, issn 0028-646X, 10 p.Article

How do weather extremes affect rice productivity in a changing climate? An answer to episodic lack of sunshineCHOI, Woo-Jung; LEE, Myoung-Seok; CHOI, Jae-Eul et al.Global change biology (Print). 2013, Vol 19, Num 4, pp 1300-1310, issn 1354-1013, 11 p.Article

No overall stimulation of soil respiration under mature deciduous forest trees after 7 years of CO₂ enrichmentBADER, Martin K.-F; KORNER, Christian.Global change biology (Print). 2010, Vol 16, Num 10, pp 2830-2843, issn 1354-1013, 14 p.Article

Time-Series Integrated Omic Analyses to Elucidate Short-Term Stress-Induced Responses in Plant Liquid CulturesDUTTA, Bhaskar; KANANI, Harin; QUACKENBUSH, John et al.Biotechnology and bioengineering. 2009, Vol 102, Num 1, pp 264-279, issn 0006-3592, 16 p.Article

Warming prevents the elevated CO₂-induced reduction in available soil nitrogen in a temperate, perennial grasslandHOVENDEN, Mark J; NEWTON, P. C. D; CARRAN, R. A et al.Global change biology (Print). 2008, Vol 14, Num 5, pp 1018-1024, issn 1354-1013, 7 p.Article

Ectomycorrhizal fungi in culture respond differently to increased carbon availabilityFRANSSON, Petra M. A; ANDERSON, Ian C; ALEXANDER, Ian J et al.FEMS microbiology ecology. 2007, Vol 61, Num 2, pp 246-257, issn 0168-6496, 12 p.Article