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1. Rapid increases in shrubland and forest intrinsic water-use efficiency during an ongoing megadrought

   https://doi.org/10.1073/pnas.2118052118  

   Kannenberg, Steven A.; Driscoll, Avery W.; Szejner, Paul; Anderegg, William R.; Ehleringer, James R. (December 2021, Proceedings of the National Academy of Sciences)

   Globally, intrinsic water-use efficiency (iWUE) has risen dramatically over the past century in concert with increases in atmospheric CO 2 concentration. This increase could be further accelerated by long-term drought events, such as the ongoing multidecadal “megadrought” in the American Southwest. However, direct measurements of iWUE in this region are rare and largely constrained to trees, which may bias estimates of iWUE trends toward more mesic, high elevation areas and neglect the responses of other key plant functional types such as shrubs that are dominant across much of the region. Here, we found evidence that iWUE is increasing in the Southwest at one of the fastest rates documented due to the recent drying trend. These increases were particularly large across three common shrub species, which had a greater iWUE sensitivity to aridity than Pinus ponderosa , a common tree species in the western United States. The sensitivity of both shrub and tree iWUE to variability in atmospheric aridity exceeded their sensitivity to increasing atmospheric [CO 2 ]. The shift to more water-efficient vegetation would be, all else being equal, a net positive for plant health. However, ongoing trends toward lower plant density, diminished growth, and increasing vegetation mortality across the Southwest indicate that this increase in iWUE is unlikely to offset the negative impacts of aridification. 

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2. Disentangling the role of photosynthesis and stomatal conductance on rising forest water-use efficiency

   https://doi.org/10.1073/pnas.1905912116  

   Guerrieri, Rossella; Belmecheri, Soumaya; Ollinger, Scott V.; Asbjornsen, Heidi; Jennings, Katie; Xiao, Jingfeng; Stocker, Benjamin D.; Martin, Mary; Hollinger, David Y.; Bracho-Garrillo, Rosvel; et al (August 2019, Proceedings of the National Academy of Sciences)

   Multiple lines of evidence suggest that plant water-use efficiency (WUE)—the ratio of carbon assimilation to water loss—has increased in recent decades. Although rising atmospheric CO 2 has been proposed as the principal cause, the underlying physiological mechanisms are still being debated, and implications for the global water cycle remain uncertain. Here, we addressed this gap using 30-y tree ring records of carbon and oxygen isotope measurements and basal area increment from 12 species in 8 North American mature temperate forests. Our goal was to separate the contributions of enhanced photosynthesis and reduced stomatal conductance to WUE trends and to assess consistency between multiple commonly used methods for estimating WUE. Our results show that tree ring-derived estimates of increases in WUE are consistent with estimates from atmospheric measurements and predictions based on an optimal balancing of carbon gains and water costs, but are lower than those based on ecosystem-scale flux observations. Although both physiological mechanisms contributed to rising WUE, enhanced photosynthesis was widespread, while reductions in stomatal conductance were modest and restricted to species that experienced moisture limitations. This finding challenges the hypothesis that rising WUE in forests is primarily the result of widespread, CO 2 -induced reductions in stomatal conductance. 

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3. Multidecadal records of intrinsic water-use efficiency in the desert shrub Encelia farinosa reveal strong responses to climate change

   https://doi.org/10.1073/pnas.2008345117  

   Driscoll, Avery W.; Bitter, Nicholas Q.; Sandquist, Darren R.; Ehleringer, James R. (August 2020, Proceedings of the National Academy of Sciences)

   null (Ed.)

   While tree rings have enabled interannual examination of the influence of climate on trees, this is not possible for most shrubs. Here, we leverage a multidecadal record of annual foliar carbon isotope ratio collections coupled with 39 y of survey data from two populations of the drought-deciduous desert shrub Encelia farinosa to provide insight into water-use dynamics and climate. This carbon isotope record provides a unique opportunity to examine the response of desert shrubs to increasing temperature and water stress in a region where climate is changing rapidly. Population mean carbon isotope ratios fluctuated predictably in response to interannual variations in temperature, vapor pressure deficit, and precipitation, and responses were similar among individuals. We leveraged the well-established relationships between leaf carbon isotope ratios and the ratio of intracellular to ambient CO 2 concentrations to calculate intrinsic water-use efficiency (iWUE) of the plants and to quantify plant responses to long-term environmental change. The population mean iWUE value increased by 53 to 58% over the study period, much more than the 20 to 30% increase that has been measured in forests [J. Peñuelas, J. G. Canadell, R. Ogaya, Glob. Ecol. Biogeogr. 20, 597–608 (2011)]. Changes were associated with both increased CO 2 concentration and increased water stress. Individuals whose lifetimes spanned the entire study period exhibited increases in iWUE that were very similar to the population mean, suggesting that there was significant plasticity within individuals rather than selection at the population scale. 

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4. Divergent water use efficiency trends among eastern North American temperate tree species

   https://doi.org/10.18130/v3/hgcf8d  

   Malcomb, Jacob (June 2024, University of Virginia Dataverse)

   The datasets included were used to analyze data for the manuscript titled "Divergent water use efficiency trends among eastern North American temperate tree species" and contain two files: (1) d13_temp_elev.csv contains tree ring stable carbon isotope ratio values for 12 tree species, the mean elevation of the watershed in which samples were collected, and the mean growing season temperature in the watershed where samples were collected; and (2) iwue_longterm_predictors.csv contains climate and atmospheric deposition data from the sites where tree core samples were collected. Climate variables represent growing season months (JJA) while atmospheric pollution variables represent annual totals. Metadata includes units, location codes, and species codes. 

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5. CO2, nitrogen deposition and a discontinuous climate response drive water use efficiency in global forests

   https://doi.org/10.1038/s41467-021-25365-1  

   Adams, Mark A.; Buckley, Thomas N.; Binkley, Dan; Neumann, Mathias; Turnbull, Tarryn L. (August 2021, Nature Communications)

   Abstract Reduced stomatal conductance is a common plant response to rising atmospheric CO₂and increases water use efficiency (W). At the leaf-scale,Wdepends on water and nitrogen availability in addition to atmospheric CO₂. In hydroclimate modelsWis a key driver of rainfall, droughts, and streamflow extremes. We used global climate data to derive Aridity Indices (AI) for forests over the period 1965–2015 and synthesised those with data for nitrogen deposition andWderived from stable isotopes in tree rings. AI and atmospheric CO₂account for most of the variance inWof trees across the globe, while cumulative nitrogen deposition has a significant effect only in regions without strong legacies of atmospheric pollution. The relation of aridity andWdisplays a clear discontinuity.Wand AI are strongly related below a threshold value of AI ≈ 1 but are not related where AI > 1. Tree ring data emphasise that effective demarcation of water-limited from non-water-limited behaviour of stomata is critical to improving hydrological models that operate at regional to global scales. 

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