Dominique Bachelet Richard T. Conant Bassil El Masri Lawrence B. Flanagan Alan K. Knapp Jinxun Liu Shuguang Liu Sean M. Schaeffer Nancy Cavallaro Gyami Shrestha Richard Birdsey Melanie A. Mayes Raymond G. Najjar Sasha C. Reed Patricia Romero-Lankao Zhiliang Zhu Elise Pendall 2018 <p>Key findings:</p><ol><li><span>Total grassland carbon stocks in the conterminous United States, estimated to be about 7.4 petagrams of carbon (Pg C) in 2005, are projected to increase to about 8.2 Pg C by 2050. Although U.S. grasslands are expected to remain carbon sinks over this period, the uptake rate is projected to decline by about half. In the U.S. Great Plains, land-use and land-cover changes are expected to cause much of the change in carbon cycling as grasslands are converted to agricultural lands or to woody biomes (medium confidence).</span></li><li><span>Increasing temperatures and rising atmospheric carbon dioxide (CO2) concentrations interact to increase productivity in northern North American grasslands, but this productivity response will be mediated by variable precipitation, soil moisture, and nutrient availability (high confidence, very likely).</span></li><li><span>Soil carbon in grasslands is likely to be moderately responsive to changes in climate over the next several decades. Field experiments in grasslands suggest that altered precipitation can increase soil carbon, while warming and elevated CO2 may have only minimal effects despite altered productivity (medium confidence, likely).</span></li><li><span> Carbon stocks and net carbon uptake in grasslands can be maintained with appropriate land management including moderate levels of grazing. Fire suppression can lead to encroachment of woody vegetation and increasing carbon storage in mesic regions, at the expense of grassland vegetation (high confidence, likely).</span></li></ol> application/pdf 10.7930/SOCCR2.2018.Ch10 en U.S. Global Change Research Program Grasslands reports