@Article{Lindsay_JClim_20141215,
 author		= {Keith Lindsay and Gordon B. Bonan and Scott C. Doney and Forrest M. Hoffman and David M. Lawrence and Matthew C. Long and Natalie M. Mahowald and J. Keith Moore and James T. Randerson and Peter E. Thornton},
 title		= {Preindustrial-Control and Twentieth-Century Carbon Cycle Experiments with the {E}arth System Model {CESM1(BGC)}},
 journal	= JClim,
 volume		= 27,
 number		= 24,
 pages		= {8981--9005},
 doi		= {10.1175/JCLI-D-12-00565.1},
 day		= 15,
 month		= dec,
 year		= 2014,
 abstract	= {Version 1 of the Community Earth System Model, in the configuration where its full carbon cycle is enabled, is introduced and documented. In this configuration, the terrestrial biogeochemical model, which includes carbon?nitrogen dynamics and is present in earlier model versions, is coupled to an ocean biogeochemical model and atmospheric CO$_2$ tracers. The authors provide a description of the model, detail how preindustrial-control and twentieth-century experiments were initialized and forced, and examine the behavior of the carbon cycle in those experiments. They examine how sea- and land-to-air CO$_2$ fluxes contribute to the increase of atmospheric CO$_2$ in the twentieth century, analyze how atmospheric CO$_2$ and its surface fluxes vary on interannual time scales, including how they respond to ENSO, and describe the seasonal cycle of atmospheric CO$_2$ and its surface fluxes. While the model broadly reproduces observed aspects of the carbon cycle, there are several notable biases, including having too large of an increase in atmospheric CO$_2$ over the twentieth century and too small of a seasonal cycle of atmospheric CO$_2$ in the Northern Hemisphere. The biases are related to a weak response of the carbon cycle to climatic variations on interannual and seasonal time scales and to twentieth-century anthropogenic forcings, including rising CO$_2$, land-use change, and atmospheric deposition of nitrogen.}
}