Publications

Displaying 121 - 140 of 322
By year of publication, then alphabetical by title
  1. Yumashev, D., et al. “Climate Policy Implications Of Nonlinear Decline Of Arctic Land Permafrost And Other Cryosphere Elements”. Nature Communications, 2019, p. 1900.
  2. Tang, J. Y., and W. J. Riley. “Competitor And Substrate Sizes And Diffusion Together Define Enzymatic Depolymerization And Microbial Substrate Uptake Rates”. Soil Biology And Biochemistry, 2019.
  3. Norby, R. J., et al. “Controls On Fine-Scale Spatial And Temporal Variability Of Plant-Available Inorganic Nitrogen In A Polygonal Tundra Landscape”. Ecosystems, 2019, pp. 528–543.
  4. Shiklomanov, A. N., et al. “Enhancing Global Change Experiments Through Integration Of Remote‐Sensing Techniques”. Frontiers In Ecology And The Environment, 2019, pp. 215 - 224.
  5. Arora, B., et al. “Evaluating Temporal Controls On Greenhouse Gas (Ghg) Fluxes In An Arctic Tundra Environment: An Entropy-Based Approach”. Science Of The Total Environment, 2019, pp. 284 - 299.
  6. Ladd, M. P., et al. “Evaluation Of An Untargeted Nano-Liquid Chromatography-Mass Spectrometry Approach To Expand Coverage Of Low Molecular Weight Dissolved Organic Matter In Arctic Soil”. Scientific Reports, 2019.
  7. Mekonnen, Z. A., et al. “Expansion Of High-Latitude Deciduous Forests Driven By Interactions Between Climate Warming And Fire”. Nature Plants, 2019, pp. 952–958.
  8. Knox, S. H., et al. “Fluxnet-Methane Synthesis Activity: Objectives, Observations, And Future Directions”. Bulletin Of The American Meteorological Society, 2019, pp. 2607–2632.
  9. Serbin, S. P., et al. “From The Arctic To The Tropics: Multibiome Prediction Of Leaf Mass Per Area Using Leaf Reflectance”. New Phytologist, 2019, pp. 1557-1568.
  10. Smith, N. G., et al. “Global Photosynthetic Capacity Is Optimized To The Environment”. Ecology Letters, 2019, pp. 506 - 517.
  11. Iizuka, Y., et al. “Ion Concentrations In Ice Wedges: An Innovative Approach To Reconstruct Past Climate Variability”. Earth And Planetary Science Letters, 2019, pp. 58 - 66.
  12. Herndon, E. M., et al. “Iron (Oxyhydr)Oxides Serve As Phosphate Traps In Tundra And Boreal Peat Soils”. Journal Of Geophysical Research: Biogeosciences, 2019, pp. 227 - 246.
  13. Natali, S. M., et al. “Large Loss Of Carbon Dioxide In Winter Observed Across The Northern Permafrost Region”. Nature Climate Change, 2019, pp. 852-857.
  14. Wang, Y., et al. “Mechanistic Modeling Of Microtopographic Impacts On Carbon Dioxide And Methane Fluxes In An Alaskan Tundra Ecosystem Using The Clm‐Microbe Model”. Journal Of Advances In Modeling Earth Systems, 2019, p. 17.
  15. Zheng, J., et al. “Modeling Anaerobic Soil Organic Carbon Decomposition In Arctic Polygon Tundra: Insights Into Soil Geochemical Influences On Carbon Mineralization”. Biogeosciences, 2019, pp. 663 - 680.
  16. Grant, R. F., et al. “Modeling Climate Change Impacts On An Arctic Polygonal Tundra: 1. Rates Of Permafrost Thaw Depend On Changes In Vegetation And Drainage”. Journal Of Geophysical Research: Biogeosciences, 2019, pp. 1308 - 1322.
  17. Grant, R. F., et al. “Modeling Climate Change Impacts On An Arctic Polygonal Tundra: 2. Changes In Carbon Dioxide And Methane Exchange Depend On Rates Of Permafrost Thaw As Affected By Changes In Vegetation And Drainage”. Journal Of Geophysicalresearch: Biogeosciences, 2019, pp. 1323 - 1341.
  18. Kumarathunge, D. P., et al. “No Evidence For Triose Phosphate Limitation Of Light‐Saturated Leaf Photosynthesis Under Current Atmospheric Carbon Dioxide Concentration”. Plant, Cell & Environment, 2019, pp. 3241 - 3252.
  19. Garayshin, V. V., et al. “Numerical Modeling Of Two-Dimensional Temperature Field Dynamics Across Non-Deforming Ice-Wedge Polygons”. Cold Regions Science And Technology, 2019, pp. 115 - 128.
  20. Vaughn, L. J. S. “Radiocarbon Evidence That Millennial And Fast-Cycling Soil Carbon Are Equally Sensitive To Warming”. Nature Climate Change, 2019, pp. 467-471.