A gradient of nutrient enrichment reveals nonlinear impacts of fertilization on Arctic plant diversity and ecosystem function. Ecology and Evolution [Internet]. 2017 ;7(7):2449 - 2460. Available from: http://onlinelibrary.wiley.com/doi/10.1002/ece3.2863/full.
High-resolution mapping of aboveground shrub biomass in Arctic tundra using airborne lidar and imagery. Remote Sensing of Environment. 2016 ;184:361 - 373..
LiDAR canopy radiation model reveals patterns of photosynthetic partitioning in an Arctic shrub. Agricultural and Forest Meteorology. 2016 ;221:78 - 93.
LiDAR gives a bird’s eye perspective on Arctic tundra breeding habitat. Remote Sensing of Environment. 2016 ;184:337-349.
Estimating aboveground biomass and leaf area of low-stature Arctic shrubs with terrestrial LiDAR. Remote Sensing Environment. 2015 ;164:26-35..
Estimating aboveground biomass of low-stature Arctic shrubs with terrestrial LiDAR. American Geophysical Union Annual Meeting. 2014 ..
Ground based remote sensing and physiological measurements provide novel insights into canopy photosynthetic optimization in arctic shrubs. American Geophysical Union Annual Meeting. 2014 ..
Implications for seamless modeling of terrestrial ecosystems (Invited Speaker). International Workshop: 3D Vegetation Mapping using Advanced Remote Sensing. 2014 ..
Thermal acclimation of shoot respiration in an Arctic woody plant species subjected to 22 years of warming and altered nutrient supply. Global Change Biology. 2014 ;20(8):2618-2630..
Differential physiological responses to environmental change promote woody shrub expansion. Ecology and Evolution [Internet]. 2013 ;3(5):1149-1162. Available from: http://dx.doi.org/10.1002/ece3.525.
Does NDVI reflect variation in the structural attributes associated with increasing shrub dominance in arctic tundra?. Environmental Research Letters. 2011 ;6(3):035501..
The role of leaf carbon exchange in arctic shrub expansion. New York, NY: Columbia University; 2009..