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“Stream Dissolved Organic Matter In Permafrost Regions Shows Surprising Compositional Similarities But Negative Priming And Nutrient Effects”. Global Biogeochemical Cycles 35. Global Biogeochemical Cycles (2021). doi:10.1029/2020gb006719.
. “Stable Isotopes Resolve The Drift Paradox For Baetis Mayflies In An Arctic River”. Ecology 74, no. 8. Ecology (1993): 2315-2325. doi:10.2307/1939584.
. “Stable Isotopes And Radiocarbon Assess Variable Importance Of Plants And Fungi In Diets Of Arctic Ground Squirrels”. Arctic, Antarctic, And Alpine Research 49, no. 3. Arctic, Antarctic, And Alpine Research (2017): 487 - 500. doi:10.1657/AAAR0016-062.
. “Stable Isotopes And Planktonic Trophic Structure In Arctic Lakes”. Ecology 73, no. 2. Ecology (1992): 561-566. doi:10.2307/1940762.
. “Stable Isotope Signatures Of Benthic Invertebrates In Arctic Lakes Indicate Limited Coupling To Pelagic Production”. Limnology And Oceanography 51, no. 1. Limnology And Oceanography (2006): 177-188. doi:10.4319/lo.2006.51.1.0177.
. “Stable Isotope Diagrams Of Freshwater Food Webs”. Ecology 72, no. 6. Ecology (1991): 2293-2297. doi:10.2307/1941580.
. “Spring Photosynthetic Onset And Net Co 2 Uptake In Alaska Triggered By Landscape Thawing”. Global Change Biology 24. Global Change Biology (2018): 3416 - 3435. doi:10.1111/gcb.14283.
. “Sporadic P Limitation Constrains Microbial Growth And Facilitates Som Accumulation In The Stoichiometrically Coupled, Acclimating Microbe–Plant–Soil Model”. Soil Biology And Biochemistry 165. Soil Biology And Biochemistry (2022): 108489. doi:10.1016/j.soilbio.2021.108489.
. “Spectral Indices For Remote Sensing Of Phytomass, Deciduous Shrubs, And Productivity In Alaskan Arctic Tundra”. International Journal Of Remote Sensing 36, no. 17. International Journal Of Remote Sensing (2015): 4344 - 4362. doi:10.1080/01431161.2015.1080878.
. “Species Responses To Nitrogen Fertilization In Herbaceous Plant Communities, And Associated Species Traits”. Ecological Archives 89, no. 4. Ecological Archives (2008): 1175. doi:10.1890/07-1104.1.
. “Species Diversity Along Nutrient Gradients: An Analysis Of Resource Competition In Model Ecosystems”. Ecosystems 7, no. 3. Ecosystems (2004): 296-310. doi:10.1007/s10021-003-0233-x.
. “Species Compositional Differences On Different-Aged Glacial Landscapes Drive Contrasting Responses Of Tundra To Nutrient Addition”. Journal Of Ecology 93. Journal Of Ecology (2005): 770-782. doi:10.1111/j.1365-2745.2005.01006.x.
. “Species Composition Interacts With Fertilizer To Control Long-Term Change In Tundra Productivity”. Ecology 82, no. 11. Ecology (2001): 3163-3181. doi:10.1890/0012-9658%282001%29082%5B3163%3ASCIWFT%5D2.0.CO%3B2.
. “Spatiotemporal Patterns Of Tundra Fires: Late-Quaternary Charcoal Records From Alaska”. Biogeosciences 12. Biogeosciences (2015): 3177-3209. doi:10.5194/bgd-12-3177-2015.
. “Spatial Variation Among Lakes Within Landscapes: Ecological Organization Along Lake Chains”. Ecosystems 2, no. 5. Ecosystems (1999): 395-410. doi:10.1007/s100219900089.
. “Sources And Partitioning Of Organic Matter In A Pelagic Microbial Food Web Inferred From The Isotopic Composition (Del 13C And Del 15N) Of Zooplankton Species”. Archiv Fur Hydrobiologie Beiheft 48. Archiv Fur Hydrobiologie Beiheft (1996): 53-61. http://www.schweizerbart.de//publications/detail/isbn/9783510470495/Archiv\_Advances\_i\_Limnol\_Heft\_48.
. “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.
. “Solar-Induced Chlorophyll Fluorescence Exhibits A Universal Relationship With Gross Primary Productivity Across A Wide Variety Of Biomes”. Global Change Biology 25, no. 4. Global Change Biology (2019): e4 - e6. doi:10.1111/gcb.14565.
. “Solar Uv Radiation In A Changing World: Roles Of Cryosphere–Land–Water–Atmosphere Interfaces In Global Biogeochemical Cycles”. Photochemical & Photobiological Sciences 18. Photochemical & Photobiological Sciences (2019): 747–774. doi:10.1039/c8pp90063a.
. “Solar Position Confounds The Relationship Between Ecosystem Function And Vegetation Indices Derived From Solar And Photosynthetically Active Radiation Fluxes”. Agricultural And Forest Meteorology 298-299. Agricultural And Forest Meteorology (2021): 108291. doi:10.1016/j.agrformet.2020.108291.
. “Soil Carbon Availability Decouples Net Nitrogen Mineralization And Net Nitrification Across United States Long Term Ecological Research Sites”. Biogeochemistry 162, no. 1. Biogeochemistry (2023): 13 - 24. doi:10.1007/s10533-022-01011-w.
. “Soil Bacterial Community Composition Altered By Increased Nutrient Availability In Arctic Tundra Soils”. Frontiers In Microbiology 5. Frontiers In Microbiology (2014): 516. doi:10.3389/fmicb.2014.00516.
. “Snail Populations In Arctic Lakes: Competition Mediated By Predation”. Oecologia 82, no. 1. Oecologia (1990): 26-32. doi:10.1007/Bf00318529.
. “Small Herbivores With Big Impacts: Tundra Voles ( Microtus Oeconomus ) Alter Post‐Fire Ecosystem Dynamics”. Ecology 103, no. 7. Ecology (2022). doi:10.1002/ecy.3689.
. “Small But Mighty: Impacts Of Rodent‐Herbivore Structures On Carbon And Nutrient Cycling In Arctic Tundra”. Functional Ecology 36, no. 9. Functional Ecology (2022): 2331 - 2343. doi:10.1111/1365-2435.14127.
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