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Bauer GA, Bazzaz FA, Minocha R, Long S, Magill A, Aber J, Berntson GM. Effects of chronic N additions on tissue chemistry, photosynthetic capacity, and carbon sequestration potential of a red pine (Pinus resinosa Ait.) stand in the NE United States.  2004;196(1):173-186.\par \par Berntson GM, Aber JD. The importance of fast nitrate immobilization in N-saturated temperate forest soils. Soil Biology and Biochemistry. 2000.\par \par Magill AH, Aber JD, Berntson GM, McDowell WH, Nadelhoffer KJ, Melillo JM, Steudler PA. Long-term nitrogen additions and nitrogen saturation in two temperate forests. Ecosystems. 2000.\par \par Li A, Godbold DL, Berntson GM, Bazzaz FA. The dynamics of root production and loss in Betula papyrifera seedlings in response to elevated CO2 and an aluminum pulse. Z. Pflanzenern. 1998;161:17-21.\par \par Berntson GM, Lynch JP, Snapp S. Fractal geometry and the description of plant root systems: current perspectives and future applications. In: Smith Chaos and Fractals in Soil Science. Chaos and Fractals in Soil Science. Boca Raton; 1998. p. 113-152.\par \par Berntson GM, Bazzaz FA. Regenerating temperate forest microcosms in elevated CO2: species composition, belowground growth and nitrogen cycling. Oecologia. 1998;113:115-125.\par \par Berntson GM, Rajakaruna N, Bazzaz FA. Species- and community-level growth and nitrogen acquisition in elevated CO2 atmospheres in an experimental annual community. Global Change Biology. 1998;4:101-120.\par \par Berntson GM, Wayne PM, Bazzaz FA. Belowground architectural and mycorrhizal responses to elevated CO2 in Betula alleghaniensis populations. Functional Ecology. 1997;11:684-695.\par \par Berntson GM, Stoll P. Correcting for finite spatial scales of self-similarity when calculating the fractal dimensions of real-world structures. Proceedings of Royal Society, Biological Sciences. 1997;264:1531-1537.\par \par Godbold DL, Berntson GM. Elevated atmospheric CO2 concentrations lead to changes in ectomycorrhizal morphotype assemblages in Betula papyrifera. Tree Physiology. 1997;17:347-350.\par \par Berntson GM, Bazzaz FA. Elevated CO2 and the magnitude and seasonal dynamics of root production and loss in Betula papyrifera. Plant and Soil. 1997;190:211-216.\par \par Godbold DL, Berntson GM, Bazzaz FA. Growth and mycorrhizal colonization of three North-American tree species under elevated atmospheric CO2. New Phytologist. 1997;137:433-440.\par \par Berntson GM, Bazzaz FA. Nitrogen cycling in microcosms of yellow birch exposed to elevated CO2: simultaneous positive and negative belowground feedbacks. Global Change Biology. 1997;3:247-258.\par \par Berntson GM. Topological scaling and plant root system architecture: developmental and functional hierarchies. New Phytologist. 1997;135:621-634.\par \par Berntson GM, Bazzaz FA. The allometry of root production and loss in seedlings of Acer rubrum (Aceraceae) and Betula papyrifera (Betulaceae): implications for root dynamics in elevated CO2. American Journal of Botany. 1996;83:608-616.\par \par Berntson GM, Bazzaz FA. Belowground positive and negative feedbacks on CO2 growth enhancement. Plant and Soil. 1996;187:119-131.\par \par Bazzaz FA, Bassow SL, Berntson GM, Thomas SC. Elevated CO2 and terrestrial vegetation: implications for and beyond the global carbon budget. In: and Steffen WBW Global Change and Terrestrial Ecosystems. Global Change and Terrestrial Ecosystems. ; 1996. p. 43-76.\par \par McConnaughay KDM, Bassow SL, Berntson GM, Bazzaz FA. Leaf senescence and decline of end-of-season gas exchange in five temperate deciduous tree species grown in elevated CO2 concentrations. Global Change Biology. 1996;2:25-34.\par \par }