More Like this

1. Revisiting the Half-and-Half Functional

   https://doi.org/10.1021/acs.jpca.5c01402  

   Gray, Montgomery; Mandal, Aniket; Herbert, John M (May 2025, The Journal of Physical Chemistry A)
2. Tree species explain only half of explained spatial variability in plant water sensitivity

   https://doi.org/10.1111/gcb.17425  

   Konings, Alexandra_G; Rao, Krishna; McCormick, Erica_L; Trugman, Anna_T; Williams, A_Park; Diffenbaugh, Noah_S; Yebra, Marta; Zhao, Meng (July 2024, Global Change Biology)

   Abstract Spatiotemporal patterns of plant water uptake, loss, and storage exert a first‐order control on photosynthesis and evapotranspiration. Many studies of plant responses to water stress have focused on differences between species because of their different stomatal closure, xylem conductance, and root traits. However, several other ecohydrological factors are also relevant, including soil hydraulics, topographically driven redistribution of water, plant adaptation to local climatic variations, and changes in vegetation density. Here, we seek to understand the relative importance of the dominant species for regional‐scale variations in woody plant responses to water stress. We map plant water sensitivity (PWS) based on the response of remotely sensed live fuel moisture content to variations in hydrometeorology using an auto‐regressive model. Live fuel moisture content dynamics are informative of PWS because they directly reflect vegetation water content and therefore patterns of plant water uptake and evapotranspiration. The PWS is studied using 21,455 wooded locations containing U.S. Forest Service Forest Inventory and Analysis plots across the western United States, where species cover is known and where a single species is locally dominant. Using a species‐specific mean PWS value explains 23% of observed PWS variability. By contrast, a random forest driven by mean vegetation density, mean climate, soil properties, and topographic descriptors explains 43% of observed PWS variability. Thus, the dominant species explains only 53% (23% compared to 43%) of explainable variations in PWS. Mean climate and mean NDVI also exert significant influence on PWS. Our results suggest that studies of differences between species should explicitly consider the environments (climate, soil, topography) in which observations for each species are made, and whether those environments are representative of the entire species range. 

   more » « less
3. US Water Pollution Regulation over the Past Half Century: Burning Waters to Crystal Springs?

   https://doi.org/10.1257/jep.33.4.51  

   Keiser, David A.; Shapiro, Joseph S. (November 2019, Journal of Economic Perspectives)
4. Mixing Accounts for More Than Half of Biogeochemical Changes Along Mode Water Ventilation Pathways

   https://doi.org/10.1029/2024GL113789  

   Jutras, M; Bushinsky, S M; Cerovečki, I; Briggs, N (April 2025, Geophysical Research Letters)

   Mode waters are critical for ocean ventilation and carbon sequestration. Using observations, we trace their subduction pathways and biogeochemical evolution. Solving modified mixing equations that account for respiration reveals that less than 50% of the oxygen changes along mode water ventilation pathways are due to respiration within the water mass, the rest being due to mixing with oxygen‐poorer surrounding waters. Consequently, measured changes in oxygen or Apparent Oxygen Utilization overestimate respiration by a factor of up to two, as do derived biogeochemical quantities such as remineralized carbon. Measured nitrate changes either overestimate or underestimate remineralization depending on surrounding concentrations. Mean true respiration rates in mode waters range from −0.1 to −0.4 mol . Applying a fixed stoichiometric ratio to this respiration, we find that the total carbon export is highest in Southern Ocean mode waters, while carbon remineralization rates are highest in subtropical mode waters. 

   more » « less
5. Double Half-Heuslers

   https://doi.org/10.1016/j.joule.2019.04.003  

   Anand, Shashwat; Wood, Max; Xia, Yi; Wolverton, Chris; Snyder, G. Jeffrey (May 2019, Joule)