Bibliography
“Long-Term Nutrient Addition Alters Arthropod Community Composition But Does Not Increase Total Biomass Or Abundance”. Oikos 127, no. 3. Oikos (2018): 460 - 471. doi:10.1111/oik.04398.
. “Long-Term Release Of Carbon Dioxide From Arctic Tundra Ecosystems In Alaska”. Ecosystems 20, no. 5. Ecosystems (2017): 960 - 974. doi:10.1007/s10021-016-0085-9.
. “Long-Term Reliability Of The Figaro Tgs 2600 Solid-State Methane Sensor Under Low-Arctic Conditions At Toolik Lake, Alaska”. Atmospheric Measurement Techniques 13, no. 5. Atmospheric Measurement Techniques (2020): 2681 - 2695. doi:10.5194/amt-13-2681-2020.
. “Long-Term Response And Recovery To Nutrient Addition Of A Partitioned Arctic Lake”. Freshwater Biology 50, no. 5. Freshwater Biology (2005): 731-741. doi:10.1111/j.1365-2427.2005.01354.x.
. “Long-Term Response Of The Kuparuk River Ecosystem To Phosphorus Fertilization”. Ecology 85, no. 4. Ecology (2004): 939-954. doi:10.1890/02-4039.
. “Long-Term Responses To Factorial, Npk Fertilizer Treatment By Alaskan Wet And Moist Tundra Sedge Species”. Ecography 18, no. 3. Ecography (1995): 259-275. doi:10.1111/j.1600-0587.1995.tb00129.x.
. “Long-Term Survival Of Adult Arctic Grayling (Thymallus Arcticus) In The Kuparuk River, Alaska”. Canadian Journal Of Fisheries And Aquatic Sciences 61, no. 10. Canadian Journal Of Fisheries And Aquatic Sciences (2004): 1954-1964. doi:10.1139/F04-126.
. “Long-Term Warming Alters The Composition Of Arctic Soil Microbial Communities”. Fems Microbiol Ecol 82, no. 2. Fems Microbiol Ecol (2012): 303-15. doi:10.1111/j.1574-6941.2012.01350.x.
. “Long-Term Warming In Alaska Enlarges The Diazotrophic Community In Deep Soils”. Mbio 10. Mbio (2019): e02521–18. doi:10.1128/mBio.02521-18.
. “Long-Term Warming Research In High-Latitude Ecosystems: Responses From Polar Ecosystems And Implications For Future Climate”. In Ecosystem Consequences Of Soil Warming. 1st ed. Ecosystem Consequences Of Soil Warming. Academic Press, 2019.
. “Long-Term Warming Restructures Arctic Tundra Without Changing Net Soil Carbon Storage”. Nature 497. Nature (2013): 615-618. doi:10.1038/nature12129.
. “Long‐Term Hydrological, Biogeochemical, And Ecological Data For The Kuparuk River, North Slope, Alaska”. Hydrological Processes 35. Hydrological Processes (2021). doi:10.1002/hyp.14115.
. “Lter And Lessons From Networked Lives.”. In Long-Term Ecological Research: Changing The Nature Of Scientists.. Long-Term Ecological Research: Changing The Nature Of Scientists. New York, NY: Oxford University Press, 2016.
. “Lter In The Arctic: Where Science Never Sleeps”. In Long Term Ecological Research: Changing The Nature Of Scientists, 91-98. Long Term Ecological Research: Changing The Nature Of Scientists. New York, NY: Oxford University Press, 2016.
. “Luxury Consumption: A Possible Competitive Strategy In Above-Belowground Carbon Allocation For Slow-Growing Vegetation?”. Journal Of Ecology 91, no. 4. Journal Of Ecology (2003): 664-676. doi:10.1046/j.1365-2745.2003.00788.x.
. “Macroinvertebrate Drift And Community Composition In An Arctic And Subarctic Stream In Alaska”. Department Of Biological Sciences. Department Of Biological Sciences. University of Cincinnati, 1986.
. “Macrosystems Ecology: Understanding Ecological Patterns And Processes At Continental Scales”. Frontiers In Ecology And The Environment 12, no. 1. Frontiers In Ecology And The Environment (2014): 5-14. doi:10.1890/130017.
. “Mammalian Herbivory Exacerbates Plant Community Responses To Long-Term Increased Soil Nutrients In Two Alaskan Tundra Plant Communities”. Arctic Science 4. Arctic Science (2018): 153-166. doi:10.1139/AS-2017-0025.
. “Maximum Summer Temperatures Predict The Temperature Adaptation Of Arctic Soil Bacterial Communities”. Biogeosciences Discussions. Biogeosciences Discussions (2022): 1–26. doi:10.5194/bg-2022-184.
. “Measuring Heterotrophic Activity In Plankton”. In Methods In Microbiology, Volume 22, 235-250. Methods In Microbiology, Volume 22. London: Academic Press, 1990.
. “Measuring Nutrient Availability In Arctic Soils Using Ion-Exchange Resins: A Field Test”. Soil Science Society Of America Journal 58, no. 4. Soil Science Society Of America Journal (1994): 1154-1162. doi:10.2136/sssaj1994.03615995005800040021x.
. “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.
. “A Mechanism Of Expansion: Arctic Deciduous Shrubs Capitalize On Warming-Induced Nutrient Availability”. Oecologia 192, no. 3. Oecologia (2020): 671 - 685. doi:10.1007/s00442-019-04586-8.
. “Mercury In The Alaskan Arctic”. In Alaska's Changing Arctic: Ecological Consequences For Tundra, Streams And Lakes, 287-302. Alaska's Changing Arctic: Ecological Consequences For Tundra, Streams And Lakes. New York, NY: Oxford University Press, 2014. doi:10.1093/acprof:osobl/9780199860401.003.0009.
. “A Meta-Analysis Of Context-Dependency In Plant Response To Inoculation With Mycorrhizal Fungi”. Ecology Letters 13, no. 3. Ecology Letters (2010): 394-407. doi:10.1111/j.1461-0248.2009.01430.x.
.