Bibliography

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2014
Nielsen L. The Chemical Map of Otoliths. [Internet]. 2014 . Available from: http://frontierscientists.com/2014/10/the-chemical-map-of-otoliths-3/
Cherry JE, Déry SJ, Cheng Y, Stieglitz M, Jacobs AS, Pan F. Climate and hydrometeorology of the Toolik Lake region and the Kuparuk River Basin: Past, present, and future. In: Hobbie JE, Kling GW A changing Arctic: Ecological consequences for tundra, streams and lakes. A changing Arctic: Ecological consequences for tundra, streams and lakes. New York, NY: Oxford University Press; 2014. pp. 21-60.
Shaver GR. Climate Change, Local Adaptatino and Arctic Plant Communities EpscoR V. Research on Adaptation to Climate Change [Internet]. 2014 . Available from: http://www.uvm.edu/~epscor/video/12_24_2014_racc_seminar_gaius_shaver.mp4
Sleighter RL, Cory RM, Kaplan LA, Abdulla HAN, Hatcher PG. A coupled geochemical and biogeochemical approach to characterize bio-reactivity of dissolved organic matter from a headwater stream. Journal of Geophysical Research: Biogeosciences. 2014 ;119(8):1520-1537.
Lynch L, Machmuller M. Digging deep under a midnight sun Laboratory CState Univ. EcoPress [Internet]. 2014 ;(September 2, 2014). Available from: http://nrelscience.org/2014/09/02/digging-deep-under-a-midnight-sun/
Bond-Lamberty B, Rocha AV, Calvin K, Holmes B, Wang C, Goulden ML. Disturbance legacies and climate jointly drive tree growth and mortality in an intensively studied boreal forest. Global Change Biology. 2014 ;20:216-227.
McGraw JB, Turner JB, Chandler JL, Vavrek MC. Disturbances as hot spots of ecotypic variation: a case study with Dryas octopetala. Arctic, Antarctic and Alpine Research. 2014 ;46:542-547.
Cameron KA, Hagedorn B, Dieser M, Christner BC, Choquette K, Sletten R, Crump BC, Kellogg CT, Junge K. Diversity and potential sources of microbiota associated with snow on western portions of the Greenland Ice Sheet. Environmental Microbiology. 2014 ;PrePrint.
Nielsen L. Droughts and Fish Highways. [Internet]. 2014 . Available from: http://frontierscientists.com/2014/10/droughts-and-fish-genetic-highways/
Gough L. Ecological monitoring at Toolik Field Station: lessons learned and challenges ahead. Arctic Biodiversity Congress. 2014 .
Bowden WB, Peterson BJ, Deegan LA, Huryn AD, Benstead JP, Golden HE, Kendrick MR, Parker SM, Schuett EB, Vallino JJ, et al. Ecology of streams of the Toolik region. In: Hobbie JE, Kling GW A changing Arctic: Ecological consequences for tundra, streams and lakes. A changing Arctic: Ecological consequences for tundra, streams and lakes. New York, NY: Oxford University Press; 2014. pp. 173-237.
Souther S, Fetcher N, Fowler Z, Shaver GR, McGraw JB. Ecotypic differentiation in photosynthesis and growth of Eriophorum vaginatum along a latitudinal gradient in the Arctic tundra. Botany. 2014 ;92(8):551-561.
Gokkaya K, Jiang Y, Rastetter EB, Shaver GR, Rocha AV. Effect of vegetation phenology and stomatal coupling on carbon and water fluxes in arctic tundra. Environmental Change Initiative Postdoc Symposium and Reception. 2014 .
DeMarco J, Mack MC, M Bret-Harte S. Effects of arctic shrub expansion on biophysical vs. biogeochemical drivers of litter decomposition. Ecology. 2014 ;95(7):1861-1875.
Heiskanen JJ, Mammarella I, Haapanala S, Pumpanen J, Vesala T, MacIntyre S, Ojala A. Effects of cooling and internal wave motions on gas transfer coefficients in a boreal lake. Tellus Series B. 2014 ;66:22827.
Mclaren JR, Gough L. Effects of increasing shrub abundance on litter production and decomposition in arctic tundra. Ecological Society of America, Annual Meeting. 2014 .
Pizano C, Baron AF, Schuur EAG, Crummer KG, Mack MC. Effects of thermo-erosional disturbance on surface soil carbon and nitrogen dynamics in upland arctic tundra. Environmental Research Letters. 2014 ;9(7):075006.
Wik M, Thornton BF, Bastviken D, MacIntyre S, Varner RK, Crill PM. Energy input is a primary controller of methane bubbling in subarctic lakes. Geophysical Research Letters. 2014 ;41(2):555-560.
Moore JC, Boone R, Koyama A, Holfelder K. Enzymatic and detrital influences on the structure, function, and dynamics of spatially-explicit model ecosystems. Biogeochemistry. 2014 ;117(1):205-227.
Greaves H, Vierling LA, Eitel JUH, Boelman NT, Griffin KL, Magney TS. Estimating aboveground biomass of low-stature Arctic shrubs with terrestrial LiDAR. American Geophysical Union Annual Meeting. 2014 .
Page SE, Logan R, Cory RM, McNeill K. Evidence for dissolved organic matter as the primary source and sink of photochemically produced hydroxyl radical in arctic surface waters. Environmental Science Process Impacts. 2014 ;16(4):807-822.
Cory RM, Ward CP, Crump BC, Kling GW. The fate of carbon draining permafrost soils is controlled by photochemical reactions in addition to microbial degradation in arctic surface waters. THAW 2014 - Thermokarst Aquatic ecosystems Workshop: Freshwater ecosystems in changing permafrost landscapes. 2014 .
Walker DA, Hamilton TD, Maier HA, Munger CA, Raynolds MK. Glacial history and long-term ecology in the Toolik Lake rgion. In: Hobbie JE, Kling GW A changing Arctic: Ecological consequences for tundra, streams and lakes. A changing Arctic: Ecological consequences for tundra, streams and lakes. New York, NY: Oxford University Press; 2014. pp. 61-80.
Dimas J. Is global warming being accelerated in the Arctic. SOURCE [Internet]. 2014 . Available from: http://source.colostate.edu/wallenstein-research/
Upton J. The good and bad climate news from permafrost melt. [Internet]. 2014 . Available from: http://www.climatecentral.org/news/good-news-bad-news-on-carbon-from-melting-permafrost-18001

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