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“Mismatch Of N Release From The Permafrost And Vegetative Uptake Opens Pathways Of Increasing Nitrous Oxide Emissions In The High Arctic”. Global Change Biology 28, no. 20. Global Change Biology (2022): 5973 - 5990. doi:10.1111/gcb.v28.20.
. “Plant Nutrient-Acquisition Strategies Change With Soil Age”. Trends In Ecology And Evolution 23, no. 2. Trends In Ecology And Evolution (2008): 95-103. doi:10.1016/j.tree.2007.10.008.
. “Arctic Warming On Two Continents Has Consistent Negative Effects On Lichen Diversity And Mixed Effects On Bryophyte Diversity”. Global Change Biology 18, no. 3. Global Change Biology (2012): 1096-1107. doi:10.1111/j.1365-2486.2011.02570.x.
. “Microbial Biogeography Of Arctic Streams: Exploring Influences Of Lithology And Habitat”. Frontiers In Microbiology 3. Frontiers In Microbiology (2012). doi:10.3389/fmicb.2012.00309.
. “Environmental Influences On The Genetic Diversity Of Bacterial Communities In Arctic Streams”. Natural Resources. Natural Resources. University of Vermont, 2009. https://scholarworks.uvm.edu/graddis/131.
. “Thermokarst And Wildfire: Effects Of Disturbances Related To Climate Change On The E Cological Characteristics And Functions Of Arctic Headwater Streams”. Natural Resources. Natural Resources. The University of Vermont, 2015. https://scholarworks.uvm.edu/graddis/520.
. “The Role Of Watershed Characteristics, Permafrost Thaw, And Wildfire On Dissolved Organic Carbon Biodegradability And Water Chemistry In Arctic Headwater Streams”. Biogeosciences Discussions 12, no. 5. Biogeosciences Discussions (2015): 4021 - 4056. doi:10.5194/bg-12-4221-2015.
. “Variability In Greenhouse Gas Emissions From Permafrost Thaw Ponds”. Limnology And Oceanography 55, no. 1. Limnology And Oceanography (2010): 115-133. doi:10.4319/lo.2010.55.1.0115.
. “Greenhouse Gas Exchange In Small Arctic Thaw Ponds”. American Geophysical Union Annual Meeting. American Geophysical Union Annual Meeting. San Francisco, CA, 2014.
. “Modeling Biogeochemical Responses Of Tundra Ecosystems To Temporal And Spatial Variations In Climate In The Kuparuk River Basin (Alaska)”. Journal Of Geophysical Research: Atmospheres 108, no. D2. Journal Of Geophysical Research: Atmospheres (2003): 8165. doi:10.1029/2001JD000960.
. “A Multivariate Approach To The Analysis Of Factorial Fertilization Experiments In Alaskan Arctic Tundra”. Ecology 63, no. 4. Ecology (1982): 1029-1038. doi:10.2307/1937242.
. “Bacterioplankton Dispersal And Biogeochemical Function Across Alaskan Arctic Catchments”. Environmental Microbiology 24, no. 12. Environmental Microbiology (2022): 5690 - 5706. doi:10.1111/1462-2920.16259.
. “A Framework For Prioritization, Design And Coordination Of Arctic Long-Term Observing Networks: A Perspective From The U.s. Search Program”. Arctic 68, no. 5. Arctic (2015): 76. doi:10.14430/arctic4450.
. “The Effects Of Aquatic Bryophytes And Long-Term Fertilization On Arctic Streams”. Journal Of The North American Benthological Society 19, no. 4. Journal Of The North American Benthological Society (2000): 697-708. doi:10.2307/1468127.
. “Nutrient Limitation Of Phytoplankton Production In Alaskan Arctic Foothill Lakes”. Hydrobiologia 455. Hydrobiologia (2001): 189-201. doi:10.1023/A:1011954221491.
. “Effects Of Vertical Hydrodynamic Mixing On Photomineralization Of Dissolved Organic Carbon In Arctic Surface Waters”. Environmental Science: Processes & Impacts 21, no. 4. Environmental Science: Processes & Impacts (2019): 748 - 760. doi:10.1039/C8EM00455B.
. “Solar-Induced Chlorophyll Fluorescence Is Strongly Correlated With Terrestrial Photosynthesis For A Wide Variety Of Biomes: First Global Analysis Based On Oco-2 And Flux Tower Observations”. Global Change Biology 24, no. 93. Global Change Biology (2018): 3990 - 4008. doi:10.1111/gcb.14297.
. “Stochastic Modeling Of Carbon Photo-Mineralization Along Arctic Rivers”. American Geophysical Union Fall Meeting. American Geophysical Union Fall Meeting. San Francisco, 2014.
. “Effects Of A Whole-Lake, Experimental Fertilization On Lake Trout In A Small Oligotrophic Arctic Lake”. Hydrobiologia 548. Hydrobiologia (2005): 51-66. doi:10.1007/s10750-005-3620-9.
. “Circum‐Arctic Distribution Of Chemical Anti‐Herbivore Compounds Suggests Biome‐Wide Trade‐Off In Defence Strategies In Arctic Shrubs”. Ecography 2022, no. 11. Ecography (2022). doi:10.1111/ecog.06166.
. “Large And Small Herbivores Have Strong Effects On Tundra Vegetation In Scandinavia And Alaska”. Ecology And Evolution 11. Ecology And Evolution (2021): 12141–12152. doi:10.1002/ece3.7977.
. “Nitrate Is An Important Nitrogen Source For Arctic Tundra Plants”. Proceedings Of The National Academy Of Sciences 115, no. 13. Proceedings Of The National Academy Of Sciences (2018): 3398 - 3403. doi:10.1073/pnas.1715382115.
. “A Biogeochemical Survey Of Rivers And Streams In The Mountains And Foot-Hills Province Of Arctic Alaska”. Archiv Fur Hydrobiologie Beiheft 115. Archiv Fur Hydrobiologie Beiheft (1989): 499-521.
. “Metabolism Of Dissolved Organic Matter By Attached Microorganisms In Rivers”. International Society For Microbial Ecology Journal 1V. International Society For Microbial Ecology Journal (1988): 367-374.
. “Colloidal And Dissolved Organic Carbon Dynamics In Undisturbed Boreal Forest Catchments: A Seasonal Study Of Apparent Molecular Weight Spectra”. Freshwater Biology 16. Freshwater Biology (1986): 187-195. doi:10.1111/j.1365-2427.1986.tb00963.x.
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