Development of an Open-source, Custom Environmental Data Logger for Spatially Scalable Data Collection

Characterizing the processes that lead to differences in ecosystem productivity and watershed hydrology across complex terrain remains a challenge. This difficulty can be partially attributed to the cost of installing networks of proprietary data loggers that monitor differences in the biophysical factors contributing to vegetation growth or hydrological processes. Studies that aim to compare concurrent time-series data sets across multiple locations must therefore balance the high cost of these data logger systems with the need for spatial resolution in their data. Here, we present the design, implementation, and case study for an open-source “Pinecone” data logger system, released under the GNU General Public License that can be manufactured for under $70 USD per unit. The system was designed to accommodate a wide range of generic and proprietary environmental sensors, and to be inexpensive enough to build and deploy large numbers to a study site. A case study was performed in which 54 data loggers were deployed to North Fork Elk Creek, a mountainous watershed located in Lubrecht Experimental Forest in the Garnet mountain range in Northwest Montana for a one year period. The data loggers were deployed across 6 hillsides in the watershed, representing combinations of differing elevations and aspects, at 9 study locations on each hillslope. At each of these locations we recorded air temperature, vapor pressure, soil water content, sap flow velocity, and tree basal area at 30 minute intervals. We evaluated the reliability of the systems in a case study over an 8 month period in 2016 and 4 month period in 2017. Our results suggest that open-source technologies such as the Pinecone logger can make it possible to develop dependable and spatially distributed sensor network within the confines of a typical research budget

Linking high-frequency DOC dynamics to the age of connected water sources

Acknowledgments The authors would like to thank our NRI colleagues for all their help with field and laboratory work, especially Audrey Innes, Jonathan Dick, and Ann Porter. We would like to also thank Iain Malcolm (Marine Scotland Science) for providing AWS data and the European Research Council ERC (project GA 335910 VEWA) for funding the VeWa project. Please contact the authors for access to the data used in this paper. We would also like to thank the Natural Environment Research Council NERC (project NE/K000268/1) for funding.Peer reviewedPublisher PD

SMALL SCALE VARIABILITY IN SNOW ACCUMULATION AND ABLATION UNDER A HETEROGENEOUS MIXED-CONIFER CANOPY

The spatial patterns of snow accumulation and melt in forested watersheds directly control runoff generation processes and the annual quantity and quality of available water to downstream receiving waters. In the western U.S. nearly three quarters of the annual water input into the hydrologic cycle comes from snow accumulation and melt in forested watersheds. This provision of water is one of the most important forest ecosystem services and is necessary for ecological, economic and social health. Despite our understanding of the coupling of forests and watersheds, the relationship between forest spatial patterns and snow hydrology is poorly understood. Forest canopies exhibit heterogeneity manifested as a mosaic of differing species, spatial arrangements, and canopy densities that differentially intercept incoming precipitation, alter wind patterns, and absorb, trap or reflect radiation; controlling the processes of snow accumulation and ablation. Vegetation patterns have been used as surrogates for processes where we expect that spatially recognizable structures give rise to specific ecological processes and vice versa. We investigated how spatial patterns of snow depth, density, snow water equivalent (SWE), and snow disappearance date (SDD) varied within stands of heterogeneous canopy structure. We collected 780 empirical measurements of snow depth, density, and SWE at peak accumulation on two fully georeferenced, mixed-conifer plots at Lubrecht Experimental Forest in western Montana. Throughout the 49 day melt season, we monitored SDD, snow depth, and SWE every third day with 4900 samples per campaign. In 2014, snow depth, density and SWE ranged from 0.0-67.31 cm, 5.43-49.76%, and 0.75-17.90 cm respectively. A canopy competition index ranged from 0.0-86.8 with non-forested areas averaging 11.5 cm SWE, melting around day 41 compared to mature dense canopy with average SWE of 5.1 cm and a SDD around day 9. This preliminary work suggests a strong linkage between canopy structure and accumulation and snowmelt processes. In the future we seek to link canopy patterns and the specific physical mechanisms that lead to differential snow dynamics in forested landscapes. This understanding is essential for improving process-based models and tools for forest managers to optimize forest water resources in a changing climate

Landscape Influences on Microclimate and Tree Growth Cessation in a Semi-arid Montane Forest

As climate change impacts the severity and frequency of drought, knowledge of hillslope-to-watershed scale ecohydrology is becoming increasingly necessary to inform appropriate conservation, restoration, and management of forested ecosystems. In mountain environments, spatial patterns of water and energy organize forest productivity at plot, hillslope, and watershed scales. These microclimatic patterns are impacted by gradients in elevation, aspect, and local topographic convergence and divergence. In water-limited systems, such patterns of moisture may be first-order drivers of intra-annual tree growth. However, there is limited field-based research characterizing how seasonal limitations of forest growth may vary across complex terrain. In 2016, continuous soil moisture, vapor pressure deficit, temperature, and radial growth were collected at 27 Douglas-fir (Psuedotsuga menziesii) sites within the Lubrecht Experimental Forest, MT. Using these data, we assessed the influences of topographic position, elevation, and aspect on hillslope-scale microclimates. These landscape and microclimatic predictors were then compared to the observed timing of tree growth cessation. Trees located in convergent topographic positions, high elevations, and north-facing aspects were correlated with decreased temperature and greater moisture, which generally led to later growth cessation. However, we also observed that perennially saturated soil conditions in some hillslope hollows resulted in earlier cessation. Overall, average microclimatic measures predicted the complex timing of growth cessation across the watershed better than static landscape proxies. These findings contribute to critical knowledge of landscape scale vegetation responses to changes in water availability, important for predicting the ramifications of climate change on forest growth

Annotated Bibliography of Research Focused on 1st-3rd Order Pygmy Rabbit (Brachylagus idahoensis) Habitat Selection

Wildlife managers often use species distribution models (SDMs) as an initial tool in conservation planning. Managers and researchers have made efforts to model the habitat and distribution of pygmy rabbits (Brachylagus idahoensis) across their historic range since the species was proposed for listing under the Endangered Species Act (USFWS 2003). Pygmy rabbits are sagebrush-obligates patchily distributed across the western United States (Green and Flinders 1980). Habitat relationships for habitat specialists like the pygmy rabbit are believed to be relatively consistent throughout their geographic range. However, appropriate spatial and temporal environmental variables at local, regional, and range-wide scales are often overlooked (Wheatley and Johnson 2009, McGarigal et al. 2016). Numerous regional and range-wide pygmy rabbit distribution models have been developed using various methodologies, environmental variables, and thresholds, resulting in predictive distribution maps that range in accuracy and usefulness. Environmental variables, such as climate or vegetation, limit species distributions at broad spatial and temporal scales (1st and 2nd order selection) (Johnson 1980). In contrast, fine-scale resource selection (3rd and 4th order) tends to be limited by local community interactions (e.g., forage availability, dispersal, predation, and competition) (Johnson 1980). For instance, the species distribution of the pygmy rabbit appears to be limited by climate, phenology, soils, and vegetation at the landscape or range-wide scale (Smith et al. 2021). Whereas dispersal, predation, and specific vegetation and soil characteristics drive resource selection at finer scales (3rd and 4th order). Integrating relevant scientific research into future pygmy rabbit modeling efforts can assist wildlife managers in focusing conservation efforts. To assist in future modeling and conservation efforts focused on pygmy rabbits, I created an annotated bibliography focused on 1st through 3rd order habitat selection. I framed the initial search using established methods utilized by the U.S. Geological Survey (USGS) (Carter et al. 2018, 2020, Kleist 2022), and then narrowed my results to include research focused on previous modeling efforts, and 1st through 3rd order habitat selection. The initial search results included over 2,000 products, which were then narrowed down to 41 peer-reviewed journal articles or technical reports. I summarized each product, focusing on habitat selection and environmental variables that could be modeled at a 30 m or greater scale. I also compiled a list of published pygmy rabbit SDMs and habitat models, the broad category of environmental variables modeled (Table 1), potential data sources, and available resolution of environmental variables used in future modeling efforts (Table 4)