Bibliography
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“Convergence In The Temperature Response Of Leaf Respiration Across Biomes And Plant Functional Types.”. Proceedings Of The National Academy Of Science 113, no. 14. Proceedings Of The National Academy Of Science (2016): 3832-3837. doi: 10.1073/pnas.1520282113.
. “Differential Physiological Responses To Environmental Change Promote Woody Shrub Expansion”. Ecology And Evolution 3, no. 5. Ecology And Evolution (2013): 1149-1162. doi:10.1002/ece3.525.
. “Early Season Respiration In Betula Nana And Eriophorium Vaginatum, Two Important Tundra Plant Species”. Department Of Ecology, Evolution And Environmental Biology. Department Of Ecology, Evolution And Environmental Biology. Columbia University, 2010.
. “Ecosystem Recovery From Disturbance Is Constrained By N Cycle Openness, Vegetation-Soil N Distribution, Form Of N Losses, And The Balance Between Vegetation And Soil-Microbial Processes”. Ecosystems. Ecosystems (2020). doi:10.1007/s10021-020-00542-3.
. “Environmental Controls Of Foliar Respiration In Arctic Tundra Plants”. Department Of Ecology, Evolution And Environmental Biology. Department Of Ecology, Evolution And Environmental Biology. Columbia University, 2013. doi:10.7916/D8HH6S87.
. “Estimating Aboveground Biomass And Leaf Area Of Low-Stature Arctic Shrubs With Terrestrial Lidar”. Remote Sensing Environment 164. Remote Sensing Environment (2015): 26-35. doi:10.1016/j.rse.2015.02.023.
. “Estimating Aboveground Biomass Of Low-Stature Arctic Shrubs With Terrestrial Lidar”. American Geophysical Union Annual Meeting. American Geophysical Union Annual Meeting. San Francisco, CA, 2014.
. “Forest Canopy Hydraulic Properties And Catchment Water Balance: Observations And Modeling”. Ecological Modelling 154. Ecological Modelling (2002): 263-288. doi:10.1016/S0304-3800(02)00068-6.
. “Global Variability In Leaf Respiration In Relation To Climate, Plant Functional Types And Leaf Traits”. New Phytologist 206, no. 2. New Phytologist (2015): 614 - 636. doi:10.1111/nph.13253.
. “A Gradient Of Nutrient Enrichment Reveals Nonlinear Impacts Of Fertilization On Arctic Plant Diversity And Ecosystem Function”. Ecology And Evolution 7, no. 7. Ecology And Evolution (2017): 2449 - 2460. doi:10.1002/ece3.2863.
. “Greater Deciduous Shrub Abundance Extends Tundra Peak Season And Increases Modeled Net Carbon Dioxide Uptake”. American Geophysical Union Annual Meeting. American Geophysical Union Annual Meeting. San Francisco, CA, 2014.
. “Greater Deciduous Shrub Abundance Extends Tundra Peak Season And Increases Modeled Net Co2 Uptake”. Global Change Biology 21, no. 6. Global Change Biology (2015): 2394-2409. doi:10.1111/gcb.12852.
. “Ground Based Remote Sensing And Physiological Measurements Provide Novel Insights Into Canopy Photosynthetic Optimization In Arctic Shrubs”. American Geophysical Union Annual Meeting. American Geophysical Union Annual Meeting. San Francisco, CA, 2014.
. “High-Resolution Mapping Of Aboveground Shrub Biomass In Arctic Tundra Using Airborne Lidar And Imagery”. Remote Sensing Of Environment 184. Remote Sensing Of Environment (2016): 361 - 373. doi:10.1016/j.rse.2016.07.026.
. “Hill Slope Variations In Chlorophyll Fluorescence Indices And Leaf Traits In A Small Arctic Watershed”. Arctic, Antarctic And Alpine Research 45, no. 1. Arctic, Antarctic And Alpine Research (2013): 39-49. doi:10.1657/1938-4246-45.1.39.
. “Implications For Seamless Modeling Of Terrestrial Ecosystems (Invited Speaker)”. International Workshop: 3D Vegetation Mapping Using Advanced Remote Sensing. International Workshop: 3D Vegetation Mapping Using Advanced Remote Sensing. St.Oswald, Germany, 2014.
. “Inter-Annual Variability Of Ndvi In Response To Long-Term Warming And Fertilization In Wet Sedge And Tussock Tundra”. Oecologia 143, no. 4. Oecologia (2005): 588-597. doi:10.1007/s00442-005-0012-9.
. “Isoprene Emissions From A Tundra Ecosystem”. Biogeosciences 10, no. 2. Biogeosciences (2013): 871 - 889. doi:10.5194/bg-10-871-2013.
. “Leaf- And Cell-Level Carbon Cycling Responses To A Nitrogen And Phosphorus Gradient In Two Arctic Tundra Species”. American Journal Of Botany 99, no. 10. American Journal Of Botany (2012): 1702-1714. doi:10.3732/ajb.1200251.
. “Lidar Canopy Radiation Model Reveals Patterns Of Photosynthetic Partitioning In An Arctic Shrub”. Agricultural And Forest Meteorology 221. Agricultural And Forest Meteorology (2016): 78 - 93. doi:10.1016/j.agrformet.2016.02.007.
. “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.
. “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.
. “Plant Diversity, Physiology, And Function In The Face Of Global Change”. Department Of Ecology, Evolution And Environmental Biology. Department Of Ecology, Evolution And Environmental Biology. Columbia University, 2017. doi:10.7916/D8K361M3.
. “Processing Arctic Eddy-Flux Data Using A Simple Carbon-Exchange Model Embedded In The Ensemble Kalman Filter”. Ecological Applications 20, no. 5. Ecological Applications (2010): 1285-1301. doi:10.1890/09-0876.1.
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