Recovery of arctic tundra from thermal erosion disturbance is constrained by nutrient accumulation: a modeling analysis. Ecological Applications. 25(5):1271-1289.
.
2015. Role of Megafauna and Frozen Soil in the Atmospheric CH4 Dynamics. Plos OnePlos OnePlos One. 9
.
2014. Constraining spatial variability of methane ebullition seeps in thermokarst lakes using point process models. Journal of Geophysical Research-BiogeosciencesJournal of Geophysical Research-BiogeosciencesJournal of Geophysical Research-Biogeosciences. 118:1015-1034.
.
2013. Long-term warming restructures Arctic tundra without changing net soil carbon storage. NatureNatureNature. 497:615-+.
.
2013. Modeling the effects of fire severity and climate warming on active layer thickness and soil carbon storage of black spruce forests across the landscape in interior Alaska. Environmental Research LettersEnvironmental Research LettersEnvironmental Research Letters. 8
.
2013. Permafrost degradation and methane: low risk of biogeochemical climate-warming feedback. Environmental Research LettersEnvironmental Research LettersEnvironmental Research Letters. 8
.
2013. The response of Arctic vegetation and soils following an unusually severe tundra fire. Philosophical Transactions of the Royal Society B-Biological SciencesPhilosophical Transactions of the Royal Society B-Biological SciencesPhilosophical Transactions of the Royal Society B-Biological Sciences. 368
.
2013. Mammoth steppe: a high-productivity phenomenon. Quaternary Science Reviews. 57:26-45.
.
2012. The Past and Future of the Mammoth Steppe Ecosystem. Paleontology in Ecology and Conservation. :193-225.
.
2012. The Effects of Snow, Soil Microenvironment, and Soil Organic Matter Quality on N Availability in Three Alaskan Arctic Plant Communities. EcosystemsEcosystemsEcosystems. 14:804-817.
.
2011. Stream geochemistry as an indicator of increasing permafrost thaw depth in an arctic watershed. Chemical GeologyChemical GeologyChemical Geology. 273:76-81.
.
2010.