Bibliography
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“Impact Of Global Change On Biogeochemistry And Ecology Of An Arctic Freshwater System”. Polar Research 18, no. 2. Polar Research (1999): 207-214. doi:10.1111/j.1751-8369.1999.tb00295.x.
. “Influence Of Morphology And Permafrost Dynamics On Hyporheic Exchange In Arctic Headwater Streams Under Warming Climate Conditions”. Geophysical Research Letters 35, no. 2. Geophysical Research Letters (2008): L02501. doi:10.1029/2007GL032049.
. “Influence Of Stream Size On Ammonium And Suspended Particulate Nitrogen Processing”. Limnology And Oceanography 46, no. 1. Limnology And Oceanography (2001): 1-13. doi:10.4319/lo.2001.46.1.0001.
. “An Integrated Assessment Of The Influences Of Upland Thermal-Erosional Features On Landscape Structure And Function In The Foothills Of The Brooks Range, Alaska”. Proceedings Of The Tenth International Conference On Permafrost. Proceedings Of The Tenth International Conference On Permafrost. Salekhard, Yamal-Nenets Autonomous District, Russia, 2012.
. “Inter-Biome Comparison Of Factors Controlling Stream Metabolism”. Freshwater Biology 46. Freshwater Biology (2001): 1503-1517. doi:10.1046/j.1365-2427.2001.00773.x.
. “The Kuparuk River: A Long-Term Study Of Biological And Chemical Processes In An Arctic River”. In Freshwaters Of Alaska, 107-130. Freshwaters Of Alaska. NY: Springer-Verlag, 1997.
. “Land-Water Interactions”. In A Changing Arctic: Ecological Consequences For Tundra, Streams And Lakes, 143-172. A Changing Arctic: Ecological Consequences For Tundra, Streams And Lakes. New York, NY: Oxford University Press, 2014. doi:10.1093/acprof:osobl/9780199860401.003.0006.
. “Linking Permafrost Thaw To Shifting Biogeochemistry And Food Web Resources In An Arctic River”. Global Change Biology. Global Change Biology (2018). doi:10.1111/gcb.14448.
. “Long-Term Effects Of Po4 Fertilization On The Distribution Of Bryophytes In An Arctic River”. Freshwater Biology 32, no. 2. Freshwater Biology (1994): 445-454. doi:10.1111/j.1365-2427.1994.tb01138.x.
. “Long-Term Measurements At The Arctic Lter Site”. In Ecological Time Series, 391-409. 1st ed. Ecological Time Series. New York: Chapman and Hall, 1995.
. “Long-Term Response Of The Kuparuk River Ecosystem To Phosphorus Fertilization”. Ecology 85, no. 4. Ecology (2004): 939-954. doi:10.1890/02-4039.
. “Measuring Thaw Depth Beneath Arctic Streams Using Ground-Penetrating Radar”. Hydrological Processes 19, no. 14. Hydrological Processes (2005): 2689-2699. doi:10.1002/Hyp.5781.
. “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.
. “Multi-Offset Gpr Methods For Hyporheic Zone Investigations”. Near Surface Geophysics 7, no. 4. Near Surface Geophysics (2009): 247-257. doi:10.3997/1873-0604.2008034.
. “Multi-Year, Spatially Extensive, Watershed-Scale Synoptic Stream Chemistry And Water Quality Conditions For Six Permafrost-Underlain Arctic Watersheds”. Earth System Science Data 14, no. 1. Earth System Science Data (2022): 95 - 116. doi:10.5194/essd-14-95-2022.
. “N Uptake As A Function Of Concentration In Streams”. Journal Of The North American Benthological Society 21, no. 2. Journal Of The North American Benthological Society (2002): 206-220. doi:10.2307/1468410.
. “Organic Matter Dynamics In The Kuparuk River, A Tundra River In Alaska, Usa”. Journal Of The North American Benthological Society 16, no. 1. Journal Of The North American Benthological Society (1997): 18-22. doi:10.2307/1468225.
. “Partitioning Assimilatory Nitrogen Uptake In Streams: An Analysis Of Stable Isotope Tracer Additions Across Continents”. Ecological Monographs 88, no. 1. Ecological Monographs (2018): 120 - 138. doi:10.1002/ecm.1280.
. “Patterns And Persistence Of Hydrologic Carbon And Nutrient Export From Collapsing Upland Permafrost”. Biogeosciences 12, no. 12. Biogeosciences (2015): 3725 - 3740. doi:10.5194/bg-12-3725-2015.
. “Profiles Of Temporal Thaw Depth Beneath Two Arctic Stream Types Using Ground-Penetrating Radar”. Permafrost And Periglacial Processes 17, no. 4. Permafrost And Periglacial Processes (2006): 341-355. doi:10.1002/ppp.566.
. “Recovery Of Arctic Tundra From Thermal Erosion Disturbance Is Constrained By Nutrient Accumulation: A Modeling Analysis”. Ecological Applications 25, no. 5. Ecological Applications (2015): 1271-1289. doi:10.1890/14-1323.1.
. “Recovery Of Three Arctic Stream Reaches From Experimental Nutrient Enrichment”. Freshwater Biology 52, no. 6. Freshwater Biology (2007): 1077-1089. doi:10.1111/j.1365-2427.2007.01723.x.
. “Responses Of Beaded Arctic Stream To Short-Term N And P Fertilization”. Freshwater Biology 50. Freshwater Biology (2005): 277-290. doi:10.1111/j.1365-2427.2004.01319.x.
. “Revealing Biogeochemical Signatures Of Arctic Landscapes With River Chemistry”. Scientific Reports 9, no. 1. Scientific Reports (2019). doi:10.1038/s41598-019-49296-6.
. “Reviews And Syntheses: Effects Of Permafrost Thaw On Arctic Aquatic Ecosystems”. Biogeosciences 12, no. 23. Biogeosciences (2015): 7129 - 7167. doi:10.5194/bg-12-7129-2015.
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