Bibliography
“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.
. “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.
. “Model Responses To Co 2 And Warming Are Underestimated Without Explicit Representation Of Arctic Small‐Mammal Grazing”. Ecological Applications 32, no. 1. Ecological Applications (2022). doi:10.1002/eap.v32.110.1002/eap.2478.
. “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 And P Constrain C In Ecosystems Under Climate Change: Role Of Nutrient Redistribution, Accumulation, And Stoichiometry”. Ecological Applications 32, no. 8. Ecological Applications (2022). doi:10.1002/eap.2684.
. “Range Shifts In A Foundation Sedge Potentially Induce Large Arctic Ecosystem Carbon Losses And Gainsabstract”. Environmental Research Letters 17, no. 4. Environmental Research Letters (2022): 045024. doi:10.1088/1748-9326/ac6005.
. “Reimagine Fire Science For The Anthropoceneabstract”. Pnas Nexus 1, no. 3. Pnas Nexus (2022). doi:10.1093/pnasnexus/pgac115.
. “Responses Of Root Phenology In Ecotypes Of Eriophorum Vaginatum To Transplantation And Warming In The Arctic”. Science Of The Total Environment 805. Science Of The Total Environment (2022): 149926. doi:10.1016/j.scitotenv.2021.149926.
. “A Review Of Open Top Chamber (Otc) Performance Across The Itex Network”. Arctic Science. Arctic Science (2022). doi:10.1139/as-2022-0030.
. “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.
. “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.
. “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.
. “Summer Thaw Duration Is A Strong Predictor Of The Soil Microbiome And Its Response To Permafrost Thaw In Arctic Tundra”. Environmental Microbiology 24, no. 12. Environmental Microbiology (2022): 6220 - 6237. doi:10.1111/1462-2920.16218.
. “Thermal Modeling Of Three Lakes Within The Continuous Permafrost Zone In Alaska Using The Lake 2.0 Model”. Geoscientific Model Development 15, no. 19. Geoscientific Model Development (2022): 7421 - 7448. doi:10.5194/gmd-15-7421-2022.
. “Variation In White Spruce Needle Respiration At The Species Range Limits: A Potential Impediment To Northern Expansion”. Plant, Cell & Environment 45, no. 7. Plant, Cell & Environment (2022): 2078 - 2092. doi:10.1111/pce.14333.
. “Vegetation Type Is An Important Predictor Of The Arctic Summer Land Surface Energy Budgetabstract”. Nature Communications 13, no. 1. Nature Communications (2022). doi:10.1038/s41467-022-34049-3.
. “Insights Into The Tussock Growth Form With Model–Data Fusion”. New Phytologist. New Phytologist (2023). doi:10.1111/nph.18751.
. “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.
.