More Like this

1. Brooks Range Treeline 2-Hourly Air Temperature (2019-2022)

   https://doi.org/10.18739/A26T0GX82  

   Sullivan, Patrick; Maher, Colin; Dial, Roman; Hewitt, Rebecca (January 2023, NSF Arctic Data Center)

   Measurements of air temperature at 2 meter height made along elevation gradients from the valley bottom to the alpine at 16 sites along a west to east gradient in the Brooks Range. The purpose of this dataset was to examine spatial variation in white spruce needle nutrition and gas exchange physiology across the Brooks Range and in relation to local microclimates. 

   more » « less
2. Brooks Range Alaska Treeline Root Nutrients and Stable Isotopes (2022)

   https://doi.org/10.18739/A25D8NH0G  

   Hewitt, Rebecca; Maher, Colin; Dial, Roman; Sullivan, Patrick (January 2025, NSF Arctic Data Center)

   Measurements of treeline white spruce fine root (<2 millimeters (mm)) carbon, nitrogen concentrations, along with stable isotopes of carbon and nitrogen. Fine roots (<2 mm) were collected from soil cores taken at the dripline below focal trees. The purpose of this dataset was to examine spatial variation in white spruce root nutrition across the Brooks Range and in relation to local microclimates. The dataset contains data for treeline trees that were treated with NPK (nitrogen, phosphorus, potassium) fertilizer at a sub-set of the research sites. 

   more » « less
3. Assessing dynamic vegetation model parameter uncertainty across Alaskan arctic tundra plant communities

   https://doi.org/10.1002/EAP.2499  

   Euskirchen, Eugénie S.; Serbin, Shawn P.; Carman, Tobey B.; Fraterrigo, Jennifer M.; Genet, Hélène; Iversen, Colleen M.; Salmon, Verity; McGuire, A. David (November 2021, Ecological Applications)

   As the Arctic region moves into uncharted territory under a warming climate, it is important to refine the terrestrial biosphere models (TBMs) that help us understand and predict change. One fundamental uncertainty in TBMs relates to model parameters, configuration variables internal to the model whose value can be estimated from data. We incorporate a version of the Terrestrial Ecosystem Model (TEM) developed for arctic ecosystems into the Predictive Ecosystem Analyzer (PEcAn) framework. PEcAn treats model parameters as probability distributions, estimates parameters based on a synthesis of available field data, and then quantifies both model sensitivity and uncertainty to a given parameter or suite of parameters. We examined how variation in 21 parameters in the equation for gross primary production influenced model sensitivity and uncertainty in terms of two carbon fluxes (net primary productivity and heterotrophic respiration) and two carbon (C) pools (vegetation C and soil C). We set up different parameterizations of TEM across a range of tundra types (tussock tundra, heath tundra, wet sedge tundra, and shrub tundra) in northern Alaska, along a latitudinal transect extending from the coastal plain near Utqiaġvik to the southern foothills of the Brooks Range, to the Seward Peninsula. TEM was most sensitive to parameters related to the temperature regulation of photosynthesis. Model uncertainty was mostly due to parameters related to leaf area, temperature regulation of photosynthesis, and the stomatal responses to ambient light conditions. Our analysis also showed that sensitivity and uncertainty to a given parameter varied spatially. At some sites, model sensitivity and uncertainty tended to be connected to a wider range of parameters, underlining the importance of assessing tundra community processes across environmental gradients or geographic locations. Generally, across sites, the flux of net primary productivity (NPP) and pool of vegetation C had about equal uncertainty, while heterotrophic respiration had higher uncertainty than the pool of soil C. Our study illustrates the complexity inherent in evaluating parameter uncertainty across highly heterogeneous arctic tundra plant communities. It also provides a framework for iteratively testing how newly collected field data related to key parameters may result in more effective forecasting of Arctic change. 

   more » « less
4. White spruce (Picea gluaca) at Brooks Range treelines in Alaska: colonists, forest advance, reproduction, recruitment, growth, and physiochemical condition, (2019-2022)

   https://doi.org/10.18739/A2V11VM9D  

   Dial, Roman J.; Maher, Colin; Hewitt, Rebecca; Wockenfuss, Amy; Wong, Russell; Sullivan, Patrick (January 2023, NSF Arctic Data Center)

   This dataset includes measurements and estimated variable values from treelines in Alaka's Brooks Range mountains. It includes locations of colonists above treelines found in 2018, 2019, 2020, 2021, and 2022; forest advance rates from the 1970s to 2010s from repeat imagery; growth rates of leaders of juveniles during 2015-2020 and lateral branch growth of adults in 2019; counts of saplings; temperatures of air at 2 meters (m) and soil at 10 centimeters (cm) from 2019-2022; soil moisture in 2019; estimated snow depth in January 2020, 2021, and 2022; foliar nitrogen and phosphorous; and foliar stable isotope ratios for nitrogen (15N:14N) and carbon (13C:12C). The purpose of the dataset is to show the effect of sea ice retreat on treeline advance. 

   more » « less
5. Brooks Range Treeline White Spruce Branch Primary Growth (2019-2022)

   https://doi.org/10.18739/A2G737544  

   Sullivan, Patrick; Hewitt, Rebecca; Maher, Colin; Dial, Roman (January 2023, NSF Arctic Data Center)

   Measurements of treeline white spruce annual branch primary growth during 2019, 2020, 2021 and 2022. Measurements were made using digital calipers on branches at breast height with persistent apical dominance. The purpose of of this dataset was to examine spatial variation in treeline white spruce branch growth across the Brooks Range and in relation to local microclimates. 

   more » « less