Articles, reporting the effects of elevated CO2, are marked with *
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* Billings S and S Ziegler. 2005. Linking microbial activity and soil organic matter transformations in forest soils under elevated CO2. Global Change Biology 11:203-212.
Butnor JR, Johnsen KH and CA Maier. 2005. Soil properties differentially influenced estimates of soil CO2 efflux from three chamber-based measurement systems. Biogeochemistry 73:283-301.
* DeLucia E, Moore D and R Norby. 2005. Contrasting responses of forest ecosystems to rising atmospheric CO2: Implications for the global C cycle. Global Biogeochemical Cycles 19(3):GB3006. [PDF]
* DeLucia EH, Moore DJ, Hamilton JG, Thomas RB, Springer CJ and RJ Corby. 2005. The Changing Role of Forests in the Global Carbon Cycle: Responding to Elevated Carbon Dioxide in the Atmosphere. In: R. Lal, J. Duxbury, B.A. Stewart and D.O. Hansen, eds. Climate Change and Global Food Security. CRC Press, Marcel Dekker. :.
* Gonzalez-Meler MA and L Taneva. 2005. Integrated effects of atmospheric CO2 concentration on plant and ecosystem respiration. In: Lambers H., Ribas-Carbo M (eds.), Plant Respiration. Kluwer-Academic Publishers. Dordrecht:211-259.
* Knepp R, Hamilton J, Mohan J, Zangerl A, Berenbaum M and E DeLucia. 2005. Elevated CO2 reduces leaf damage by insect herbivores in a forest community. New Phytologist 167:207-218. [PDF]
* Lichter J, Barron S, Finzi A, Irving K, Roberts M, Stemmler E and W Schlesinger. 2005. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO2 enrichment. Ecology 86(7):1835-1847. [PDF]
* McElrone AJ, Reid CD, Hoye KA,Hart E and RB Jackson. 2005. Elevated CO2 reduces disease incidence and severity of a red maple fungal pathogen via changes in host physiology and leaf chemistry. Global Change Biology 11:1828-1836. [PDF]
Montaldo N, Rondena R, Albertson JD and M Mancini. 2005. Parsimonious modeling of vegetation dynamics for ecohydrologic studies of water-limited ecosystems Water Resources Research 41(10):W10416, doi:10.1029/2005WR004094. [PDF]
Mortazavi B, Chanton J, Prater J, Oishi C, Oren R and G Katul. 2005. Temporal variability in 13C of respired CO2 in a pine and a hardwood forest subject to similar climatic conditions. Oecologia 142:57-69. [PDF]
* Norby R, DeLucia E, Gielen B, Calfapietra C, Giardina C, King J, Ledford J, McCarthy H, Moore D, Ceulemans R, De Angelis P, Finzi A, Karnosky D, Kubiske M, Lukac M, Pregitzer K, Scarascia-Mugnozza G, Schlesinger W, Oren R. 2005. Forest response to elevated CO2 is conserved across a broad range of productivity. Proceedings of the National Academy of Sciences 102:18052-18056. [PDF]
Palmroth S, Maier C, McCarthy H, Oishi C, Kim H-S, Johnsen K, Katul G and R Oren. 2005. Contrasting responses to drought of forest floor CO[sub]2[/sub] efflux in a Loblolly pine plantation and a nearby Oak-Hickory forest. Global Change Biology 11:421-434. [PDF]
* Springer C, DeLucia E and R Thomas. 2005. Relationships between net photosynthesis and foliar nitrogen concentrations in a loblolly pine forest ecosystem grown in elevated atmospheric carbon dioxide. Tree Physiology 25(4):385-394. [PDF]
Stoy P, Katul G, Siqueira M, Juang J, McCarthy H, Kim H, Oishi A and R Oren. 2005. Variability in net ecosystem exchange from hourly to inter-annual time scales at adjacent pine and hardwood forests: a wavelet analysis Tree Physiology 25(7):887-902. [PDF]
White LW, Luo Y and T Xu. 2005. Carbon sequestration: inversion of FACE data and prediction. Applied Mathematics and Computation 163:783-800. [PDF]
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