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  • Asner GP, Elmore AJ, Olander LP, Martin RE, Harris T (2004) Grazing systems, ecosystem responses, and global change. Annual Review of Environment and Resources, 29, 261299.
  • Bias Corrected and Downscaled World Climate Research Programme. Bias Corrected and Downscaled WCRP CMIP3 Climate Projections. Available at: http://gdo-dcp.ucllnl.org/downscaled_cmip3_projections (accessed 20 September 2012).
  • Bracmort K (2010) Meeting the Renewable Fuel Standard (RFS) Mandate for Cellulosic Biofuels: Questions and Answers. Research Serv. Report for Congress, RL41106.
  • Bracmort K, Schnepf R, Stubbs M, Yacobucci BD (2010) Cellulosic biofuels: Analysis of policy issues for congress. Cong. Research Serv. Report for Congress, RL34738.
  • Bransby DI, Mclaughlin SB, Parrish DJ (1998) A review of carbon and nitrogen balances in switchgrass grown for energy. Biomass and Bioenergy, 14, 379384.
  • Bunn AG, Goetz SJ, Fiske GJ (2005) Observed and predicted responses of plant growth to climate across Canada. Geophysical Research Letters, 32, 14.
  • Buyx A, Tait J (2011) Ethical framework for biofuels. Science, 332(6029), 540541.
  • Dalrymple RL, Don DD (1967) Root and shoot growth of five range grasses. Journal of Range Management, 20, 141145.
  • Dunn AL, Barford CC, Wofsy SC, Goulden ML, Daube BC (2007) A long-term record of carbon exchange in a boreal black spruce forest: means, responses to interannual variability, and decadal trends. Global Change Biology, 13, 577590.
  • Frank AB, Berdahl JD, Hanson JD, Liebig MA, Johnson HA (2004) Biomass and carbon partitioning in Switchgrass. Crop Science, 44, 13911396.
  • Gelfand I, Snapp SS, Robertson GP (2010) Energy efficiency of conventional, organic, and alternative cropping systems for food and fuel at a site in the U.S. Midwest. Environmental Science & Technology, 44, 40064011.
  • Gu Y, Wylie BK (2010) Detecting ecosystem performance anomalies for land management in the Upper Colorado River Basin using satellite observations, climate data, and ecosystem models. Remote Sensing, 2(8), 18801891.
  • Gu Y, Boyte SP, Wylie BK, Tieszen LL (2012) Identifying grasslands suitable for cellulosic feedstock crops in the Greater Platte River Basin: dynamic modeling of ecosystem performance with 250 m eMODIS. GCB Bioenergy, 4, 96106.
  • Gu Y, Wylie BK, Bliss NB (2013) Mapping grassland productivity with 250-m eMODIS NDVI and SSURGO database over the Greater Platte River Basin, USA. Ecological Indicators, 24, 3136.
  • Guretzky JA, Biermacher JT, Cook BJ, Kering MK, Mosali J (2011) Switchgrass for forage and bioenergy: harvest and nitrogen rate effects on biomass yields and nutrient composition. Plant and Soil, 399, 6981.
  • Henderson BL, Bui EN, Moran CJ, Simon DAP (2005) Australia-wide predictions of soil properties using decision trees. Geoderma, 124, 383398.
  • Homer C, Huang C, Yang L, Wylie B, Coan M (2004) Development of a 2001 national land-cover database for the United States. Photogrammetric Engineering and Remote Sensing, 70, 829840.
  • Kang S, Kimball JS, Running SW (2006) Simulating effects of fire disturbance and climate change on boreal forest productivity and evapotranspiration. Science of the Total Environment, 362, 85102.
  • Kimball JS, Zhao M, Mcdonald KC, Running SW (2006) Satellite remote sensing of terrestrial net primary production for the pan-Arctic basin and Alaska. Mitigation and Adaptation Strategies for Global Change, 11, 783804.
  • Launchbaugh K, Brammer B, Brooks ML et al. (2008) Interactions among livestock grazing, vegetation type, and fire behavior in the Murphy Wildland Fire Complex in Idaho and Nevada, July 2007. USGS Open-File Report, 2008–1214Reston, VA, USA.
  • Liebig MA (2006) USDA and DOE favor switchgrass for biomass fuel. Industrial Bioprocessing, 28, 7.
  • Liebig M, Schmer M, Vogel K, Mitchell R (2008) Soil carbon storage by switchgrass grown for bioenergy. Bioenergy Research, 1, 215222.
  • Ma Z, Wood CW, Bransby DI (2000) Carbon dynamics subsequent to establishment of switchgrass. Biomass and Bioenergy, 18, 93104.
  • Mclaughlin SB, Kszos LA (2005) Development of switchgrass (Panicum virgatum) as a bioenergy feedstock in the United States. Biomass and Bioenergy, 28, 515535.
  • Meinshausen M, Smith SJ, Calvin KV et al. (2011) The RCP Greenhouse Gas Concentrations and Their Extensions from 1765 to 2300. Climatic Change, 109, 213241.
  • Monti A, Barbanti L, Zatta A, Zegada-Lizarazu W (2012) The contribution of switchgrass in reducing GHG emissions. GCB Bioenergy, 4, 420434.
  • Moss RH, Edmonds JA, Hibbard KA et al. (2010) The next generation of scenarios for climate change research and assessment. Nature, 463, 747756.
  • Pala C (2010) Study finds using food grain to make ethanol is energy-inefficient. Environmental Science & Technology, 44, 3648.
  • Perrin R, Vogel K, Schmer M, Mitchell R (2008) Farm-scale production cost of switchgrass for biomass. BioEnergy Research, 1, 9197.
  • Pimentel D (2010) Corn and cellulosic etanol problems and soil erosion.(ed. In: Soil quality and biofuel production. (edsLal R, Stewart BA), pp. 119135. CRC Press, Taylor&Francis Group, Boca Raton, FL, USA.
  • Rinehart L (2006) Switchgrass as a bioenergy crop. A publication of ATTRA - National Sustainable Agriculture Information Service. Available at: https://attra.ncat.org/attra-pub/summaries/summary.php?pub=311 (accessed 25 February 2013).
  • Rupp TS, Chapin Iii FS, Starfield AM (2000) Response of subarctic vegetation to transient climatic change on the Seward Peninsula in north-west Alaska. Global Change Biology, 6, 541555.
  • Sanderson MA, Read JC, Reed RL (1999) Harvest management of switchgrass for biomass feedstock and forage production. Agronomy Journal, 91, 510.
  • Sanderson MA, Adler PR, Boateng AA, Casler MD, Sarath G (2006) Switchgrass as a biofuels feedstock in the USA. Canadian Journal of Plant Science, 86, 13151325.
  • Saxon E, Baker B, Hargrove W, Hoffman F, Zganjar C (2005) Mapping environments at risk under different global climate change scenarios. Ecology Letters, 8, 5360.
  • Schmer MR, Mitchell RB, Vogel KP, Schacht WH, Marx DB (2010) Spatial and temporal effects on switchgrass stands and yield in the Great Plains. Bioenergy Research, 3, 159171.
  • Schmer MR, Vogel KP, Mitchell RB, Perrin RK (2008) Net energy of cellulosic ethanol from switchgrass. Proceedings of the National Academy of Sciences, 105, 464469.
  • Schnepf R, Yacobucci BD (2010) Selected issues related to an expansion of the Renewable Fuel Standard (RFS). Cong. Research Serv. Report for Congress, R40155.
  • Searchinger T, Heimlich R, Houghton RA et al. (2008) Use of U.S. croplands for biofuels increases greenhouse gases through emissions from land-use change. Science, 319, 12381240.
  • Simpson T (2009) Biofuels: the past, present, and a new vision for the future. BioScience, 59, 926927.
  • Sladden SE, Bransby DI, Aiken GE (1991) Biomass yield, composition and production costs for 8 switchgrass varieties in Alabama. Biomass and Bioenergy, 1, 119122.
  • Smart AJ, Dunn BH, Johnson PS, Xu L, Gates RN (2007) Using weather data to explain herbage yield on three Great Plains plant communities. Rangeland Ecology and Management, 60, 146153.
  • Solomon BD, Barnes JR, Halvorsen KE (2007) Grain and cellulosic ethanol: history, economics, and energy policy. Biomass and Bioenergy, 31, 416425.
  • Tieszen LL, Reed BC, Bliss NB, Wylie BK, Dejong DD (1997) NDVI, C3 AND C4 production, and distributions in Great Plains grassland land cover classes. Ecological Applications, 7, 5978.
  • Trostle R (2008) Global Agricultural Supply and Demand: Factors Contributing to the Recent Increase in Food Commodity Prices. Economic Research Service, WRS-0801. US Department of Agriculture, Washington, DC, USA.
  • Vadas PA, Barnett KH, Undersander DJ (2008) Economics and energy of ethanol production from Alfalfa, Corn, and Switchgrass in the Upper Midwest, USA. Bioenergy Research, 1, 4455.
  • Viereck LA, Van Cleve K, Dyrness CT (1984) Some aspects of vegetation and temperature relationships in the Alaska taiga. In: The Potential Effects of Carbon-dioxide-Induced Climate Changes In Alaska(ed. Mcbeath JH), pp. 129142. University of Alaska, Fairbanks, AK, USA.
  • Viereck LA, Dyrness CT, Batten AR, Wenzlick KJ (1992) The Alaskan vegetation classification. USDA Pacific Northwest Research Station General Technical ReportPortland, OR, USA.. PNW-GTR-286.
  • Vogel KP, Brejda JJ, Walters DT, Buxton DR (2002) Switchgrass biomass production in the Midwest USA: harvest and nitrogen management. Agron J, 94, 413420.
  • White AB, Kumar P, Tcheng D (2005) A data mining approach for understanding topographic control on climate-induced inter-annual vegetation variability over the United States. Remote Sensing of Environment, 98, 120.
  • Wylie BK, Denda I, Pieper RD, Harrington JA, Reed BC, Southward GM (1995) Satellite-based herbaceous biomass estimates in the pastoral zone of Niger. Journal of Range Management, 48, 159164.
  • Wylie BK, Fosnight EA, Gilmanov TG, Frank AB, Morgan JA, Haferkamp MR, Meyers TP (2007) Adaptive data-driven models for estimating carbon fluxes in the northern Great Plains. Remote Sensing of Environment, 106, 399413.
  • Wylie BK, Zhang L, Bliss NB, Ji L, Tieszen LL, Jolly WM (2008) Integrating modelling and remote sensing to identify ecosystem performance anomalies in the boreal forest, Yukon River Basin, Alaska. International Journal of Digital Earth, 1, 196220.
  • Wylie BK, Boyte SP, Major DJ (2012) Ecosystem performance monitoring of rangelands by integrating modeling and remote sensing. Rangeland Ecology and Management, 65, 241252.
  • Zeri M, Anderson-Teixeira K, Hickman G, Masters M, Delucia E, Bernacchi CJ (2011) Carbon exchange by establishing biofuel crops in Central Illinois. Agriculture, Ecosystems, & Environment, 144, 319329.