2018 Forest Ecosystem Monitoring Cooperative Conference

Authors: Sam Bietsch, National Park Service, Northeast Temperate Inventory and Monitoring, Bar Harbor, ME
Kathryn Miller, National Park Service, Northeast Temperate Inventory and Monitoring, Bar Harbor, ME
Camilla Seirup, National Park Service, Northeast Temperate Inventory and Monitoring, Bar Harbor, ME
Aaron Weed, National Park Service, Northeast Temperate Inventory and Monitoring Network, Woodstock, VT

The Northeast Temperate Network Inventory & Monitoring Program (NETN) has been monitoring forest health annually in Acadia National Park since 2006. NETN monitors a suite of site and vegetation measures across a network of 176 randomly located permanent plots in Acadia. Plots are sampled on a 4-year rotating panel, such that one quarter of plots are sampled every year, and each plot is sampled every 4 years. Currently each plot has been sampled at least 3 times, allowing us to begin examining forest trends in Acadia. Overall patterns indicate that forests are succeeding to older successional stages. While this pattern is most apparent on the east side of Mount Desert Island, signals of succession are evident park-wide. Shade tolerant species are increasing in abundance, while early successional species like paper birch (Betula papyrifera) are declining. Most notably, red spruce (Picea rubens) is increasing in abundance across all strata in the forest, including seedlings, saplings, and canopy trees. Red spruce is also the most abundant understory species, occupying nearly double the percent cover of the next most abundant species of black huckleberry (Gaylussacia baccata) and lowbush blueberry (Vaccinium angustifolium). Invasive species continue to be at low levels, with invasive species documented in only 5 out of 176 plots. Red pine (Pinus resinosa) mortality from red pine scale (Matsucoccus resinosae) has been observed in the most recent 4-year cycle, although less than 1% of trees monitored by NETN in ACAD are red pine. As long as forest composition metrics remain stable (e.g., no new invasive species, stable tree condition/ forest pests, and continued regeneration), late-successional structure is expected to continue developing over time.

Authors: James Duncan, UVM, RSENR, FEMC
Alexandra Kosiba, UVM, RSENR, FEMC
Mike Finnegan, UVM, RSENR, FEMC
John Truong, UVM, RSENR, FEMC

In 2017 FEMC rebranded from the Vermont Monitoring Cooperative to the Forest Ecosystem Monitoring Cooperative. FEMC was built upon the long-term environmental monitoring initiated by the VMC in 1990. While retaining the role of managing forest ecosystem data in Vermont, FEMC has expanded their reach to organizations and agencies outside of Vermont and built various projects to meet our partner's needs. These projects include; an assessment of hemlock wooly adelgid-induced losses in corridors in New York state, a clearcut inventory in the state of New Hampshire with the New Hampshire Department of Forests and Lands (NHDFL), a catalog and access portal for researchers, managers, and educators in the Catskills region of New York with the Catskills Science Collaborative, a data entry portal for the Vermont Center for Ecostudies to use with their volunteer Mountain Bird Watch program.

Authors: Stephen Rotella, UVM, RSENR, FEMC
Josephine Robertson, UVM, RSENR, FEMC
Danielle Ward, UVM, RSENR, FEMC
Gene O. Desideraggio, UVM, RSENR, FEMC
John Truong, UVM, RSENR, FEMC
James Duncan, UVM, RSENR, FEMC

In 1991, the Forest Ecosystem Monitoring Cooperative, formerly the Vermont Monitoring Cooperative, and the Vermont Department of Forests, Parks and Recreation created a statewide forest health monitoring network, designed to uncover important relationships, changes, and stressors impacting Vermont's forested landscape. The plots were initially located in intensive study sites on Mt. Mansfield and in the Lye Brook Wilderness area and were surveyed annually. The FHM network contains 49 plots by co-locating with other forest health monitoring efforts such as the USFS Forest Inventory and Analysis, the North American Maple Project, and others. The expansion better represents a cross-section of Vermont's forests and long-term trends in forest health.

Authors: John Butnor, USDA Forest Service

Montane environments create a range meteorological conditions in a relatively small area, creating islands of plant and animal communities usually found at higher latitudes. Sensitivities to climate along elevation gradients can affect species distribution and within species, differences in phenology. In much of Vermont, red spruce (Picea rubens) exists in the ecotone between high and low elevation forests. It thrives in humid environs that are neither too cold nor too warm and there is some evidence that adaptations to climate exist in high and low elevation populations that are geographical very close to each other. To better understand the selective pressure of climate gradients on red spruce a series of 7 data loggers that record air temperature and humidity every hour were installed along the Burrows trail on the western slope of Camel's Hump (570 m to 1113 m). For calendar year 2017, mean annual temperature and humidity ranged from 2.0 ?C and 93.3 % at 1113 m to 5.8 ?C and 82.6 % at 570 m. Variation in both mean annual air temperature (R2= 0.99) and relative humidity (R2 = 0.77) were linearly related to elevation. The mean temperature difference of 3.8 ?C was observed over < 2.5 aerial km. Diurnal and seasonal patterns will be discussed.

Authors: Marie Ambusk, Co-Founder
Gordon Mann, Co-Founder

The unintended consequences of container grown nursery stock trees have been clearly documented and understood by the industry. While attempts to build a “better mouse trap” have focused on the container designs, and nursery production practices, the current recommended methods to inspect the quality of a tree’s root system are: 1) use bare root stock, or 2) wash the soil off roots for container or b&b stock. The current practice to mitigate container root problems is to cut off the outer inch of the root ball before planting. These approaches do not solve the problem or allow reasonable verification of root system quality, and all depend on the person doing the planting to make the decisions. The pragmatic challenge can be defined as: It’s hard to fix what you can’t see! Buyers purchase millions of trees without knowing the quality of the root systems, and many don’t realize they are receiving a poor-quality product. Those buyers that specify a quality level cannot confirm that every tree meets their specifications. How can one specify and confirm root system quality without seeing the roots? After delivery, the person planting the tree typically does not fix the root problems. The result is that the tree owner does not receive a high-quality tree asset. TREES ROI is using noninvasive ground penetrating radar (GPR) technology to image root systems and measure quality. This innovation will allow the assessment of root systems to identify problems and consider appropriate action needed for correction, from the earliest stages of nursery production up to the day the trees are delivered for planting. The method uses GPR technology with three-dimensional (3D) visualization software to provide an image of the root system. It will allow growers to invest in viable plants through the entire growing cycle and will give buyers an objective confidence in root quality with visual assurance to support the purchase and installation of quality plants. It will also allow root quality specifications to be verified and confirm plants meet quality benchmark specifications. In preliminary testing, we identified tree root system and GPR complexities for further analysis to be addressed at Geophysical Survey System Inc (GSSI’s) Innovation Lab. The next steps will be to develop an enhanced 3D image, determine the best application of GPR technology to meet our requirements, and to combine our root defect recognition software with the system design. Our goal is to have a prototype for testing in 2019 and a viable tool for the industry in 2020. We look forward to achieving our vision to improve the value, benefits and lifespan of container grown tree stock and to grow better urban trees – a WIN-WIN! That is good Return On Investment; ... at the Root Of It.

Authors: Kent P. McFarland, Vermont Center for Ecostudies, Norwich, VT
Leif L. Richardson, Gund Institute for Ecological Economics, University of Vermont, Burlington, VT
Sara Zahendra, Vermont Center for Ecostudies, Norwich, VT
Spencer Hardy,Vermont Center for Ecostudies, Norwich, VT

Bombus spp. (bumble bees) play key roles as pollinators in temperate ecosystems. Some North American species have declined due to factors that include habitat loss, parasites, pesticides, and climate change. In many regions, conservation is hampered by lack of quantitative data on historical abundance and distribution, making status assessments difficult. From 2012 to 2014, with help from 53 citizen scientists, we conducted surveys to determine the status of bumble bees throughout Vermont. For historical comparison, we determined species identifications and databased bumble bee specimen data from 24 public and private collections. Our dataset contained 12,319 valid records, which we separated into historic (1915–1999; n = 1669) and modern (2000–2014; n = 10,650) periods, with our survey contributing 91% of modern data. Of 17 species, 4 were extirpated and 4 showed significant declines. Rarefaction indicated that both modern and historic datasets slightly underestimated true species richness, diversity, and abundance, but confirmed a strong decline for all 3 parameters. Declining species broadly accorded with those reported elsewhere in eastern North America, and included those in subgenera Bombus and Psithyrus, as well as Bombus fervidus and B. pensylvanicus. Four species in the subgenus Pyrobombus (B. bimaculatus, B. impatiens, B. ternarius, and B. vagans) increased strongly in relative abundance in the modern period. Landscape factors such as road density, elevation, and land use strongly predicted distribution of some species. Species diversity was correlated positively with grasslands, and negatively with deciduous and mixed forest cover, while abundance was correlated positively with evergreen forest cover, yet negatively with deciduous forest.

Authors: Kacey Clougher, UVM
James Duncan, UVM, FEMC
Alexandra Kosiba, UVM, FEMC

Forested watersheds of Vermont provide the state with a large portion of its water supply. As Vermont is losing its canopy cover the effect on quality and quantity is unknown. Although there have been many studies looking at the linkage between change in land cover and discharge from streams, many of these studies reflect drastic changes in land cover such as clear cutting or human development. The objective of this study was to quantify the percentage of water that passes through forested watersheds and observe the relationship between forest canopy cover and in catchment trends over time. Daily discharge measurements for summer months were taken from USGS stream gauge data and quantified for runoff measurements specific to the size of the catchment basin of that gauge. National Land Cover Database (NLCD) provides 30 meter resolution estimates of percent forest canopy for 2001 and 2011 in which changes in canopy cover percentage were taken and averaged across 144 months to get an approximate rate of change. The average canopy cover changes ranged from +1.02% canopy cover growth to -3.34% canopy cover loss from 2001 to 2011. These basins saw little change in overall discharge trends between 2001 and 2011, however historical records dating from 1940’s to 1970’s indicate that over the century the same basin has seen a trend of increased runoff. A few basins had larger changes in forest canopy cover, between -5.64% to -7.54% loss from 2001 to 2011, showed a significant change in increased runoff over the 10 year period. Though limited by lack of temporal data of canopy cover prior to 2001, historical data shows long term trends of increased runoff values. This study supports that gradual loss of percent canopy cover of a forested stream is reflected in changes in runoff trends. Increased runoff from these basins could mean increased runoff trends in Vermont’s forest basins and impact the state’s water supply.

Authors: Risa Berman, Saint Michael's College
Lauren Dunn, Saint Michael's College
Declan McCabe PhD, Saint Michael's College

Features such as logs, trails, and waterways in forest ecosystems have the potential to serve as pathways or barriers for animals, and therefore influence species richness and abundance in these areas. The Saint Michael’s College Natural Area in Colchester, Vermont encompasses 340 acres of second-growth forest, wetland, and agricultural fields with many downed logs. Twenty-one wildlife cameras were deployed throughout this area to investigate whether the presence of logs influences species abundance and richness. Two different types of sites were compared: sites with a log present (n=6), and sites in unobstructed open or forested areas (n=15). Cameras at sites with logs were positioned to capture still images of animals on or near the logs. The cameras collected data between July and October 2018. For each camera site, the total number of observations of each species was recorded. For the cameras at sites with logs, we also noted if the animal was seen on or off the log. We recorded greater abundance and species richness from sites with logs versus the areas that lacked logs. Species observed included raccoons, opossums, hawks, red squirrels, gray squirrels, gray foxes, ravens, crows, chipmunks, mice, white tailed deer, coyotes, rabbits, various small bird species, woodchucks, turkeys, skunks, and weasels. The results of this study also provide insight into the biodiversity of a suburban natural area and microhabitat usage of different species that occur there.

Authors: Vickie Backus, Middlebury College
Alison Nurok, Middlebury College
The students of BIOL0140 Ecology and Evolution 2007 to 2018, Middlebury College

In this poster we will present data on long term patterns of mayfly density and proportional representation in the benthic macroinvertebrate population (BMI) of the New Haven and Middlebury Rivers in Addison County VT. Mayflies are an important group of BMI as they can live in more different kinds of habitats than other BMI (Voshell, 2012), and are generally the dominant order in our field sites (unpublished data). They are also important indicators of water quality (Alhejoj et al. 2014). We have noticed over the past 10 years that the density of mayflies varies greatly from year to year in our Autumn collections. Some of this variation is due to large storms especially during the years 2010-2012; however large storms do not occur every year. Given the prediction that climate change may increase the magnitude and frequency of large storms in the northeast it is important to understand long term patterns in BMI abundance.

Authors: Jennifer Santoro, University of Vermont
Anthony D'Amato, University of Vermont

Global climate change is predicted to have significant but unknown impacts on future forest structure, function, and composition in New England. Combined with a mixed-ownership landscape and dynamic land use history in this region, it may be challenging to meet diverse landowner management objectives using historic silvicultural techniques under future changing conditions. The Adaptive Silviculture for Climate Change (ASCC) project, which aims to provide a toolbox of approaches to forest management for many outcomes under global change, can be employed to break down barriers to communication and implementation between scientists and landowners, resulting in the creation of silvicultural strategies that are both attainable and promote forest resiliency in the face of future changes. This research integrates field measurements from an operational field study at the Second College Grant ASCC project site in Coos County, New Hampshire, with LANDIS-II landscape simulation models to model future forest conditions based on projected changes in climate, disturbance, and associated management regimes. It involves four main management approaches: resistance, resilience, transition, and no management treatments. These stochastic models allow us to evaluate the effectiveness of various adaptive silvicultural strategies at sustaining forest structure, composition, ecosystem services, and landowner management objectives in the context of a changing and uncertain climate future. Resilience and transition treatments are projected to fare the best in terms of maintained ecosystem services under simulated climate models by employing uneven-aged management strategies that emphasize species diversity, structural heterogeneity, and the influx of climate-adapted species. This work underscores the utility of landscape simulation models for evaluating the outcomes of adaptive silviculture and its impacts on future forest structure, function, and composition so as to aid decision making under an uncertain climate future.

Authors: Jonathan Rosenthal, Ecological Research Institute
Radka Wildova, Ecological Research Institute
Pieter van Loon, Vermont Land Trust
Liz Thompson, Vermont Land Trust
Dan Kilborn, Vermont Land Trust
Caitlin Cusack, Vermont Land Trust
David McMath, Vermont Land Trust

The detection of emerald ash borer (EAB) in Vermont in 2018 realized a threat that the forestry community had been anticipating for years. With the potential to kill nearly all of the state's 150 million white, green, and black ash trees, including significant components of upland forest stands, extensive forested wetlands, and municipal street tree populations, EAB will undoubtedly change Vermont's landscape in complex ways. There is a high level of interest in and awareness of EAB in Vermont, and a strong desire on the part of foresters, landowners, and others with deep ties to the woods for practical management and response options, especially those that can promote long-term ash survival. Some hope resides in research from the US Forest Service on "lingering ash" trees, which can serve as a source for breeding EAB-resistant, locally adapted, native ash for eventual restoration. Vermont Land Trust (VLT) holds conservation easements on over 2500 properties, comprising over 420,000 acres of forestland, and has ongoing stewardship relationships with thousands of landowners. With such a large base of acres and people, VLT serves as an important resource for land management information, including the evolving best practices, emerging from ongoing research, on managing forestland in the face of EAB. Beginning in spring 2018, VLT foresters and ecologists have worked with scientists at Ecological Research Institute (ERI) to participate in their Monitoring and Managing Ash (MaMA) citizen science program. MaMA incorporates constructive steps for each stage of EAB invasion, from pre-invasion to aftermath forest, to help promote ash conservation in light of this invasive threat. In particular, it includes protocols that enable 1) documenting first detection and current status of EAB in a local area; 2) using the MaMA Monitoring Plots Network to assess local EAB-induced ash mortality in order to determine when areas throughout the network can be searched for lingering ash trees; and 3) reporting of lingering ash trees. In summer 2018, VLT foresters and ecologists set up plots in the MaMA Monitoring Plots Network on three pieces of conserved land in Arlington, Starksboro, and Williamstown. Plots are centered around ash swamps, but all also include trees in adjacent upland areas, and trees of multiple ash species. These are the first such plots in Vermont and are part of a larger VLT response to EAB. Additional information on the MaMA program can be found at MonitoringAsh.org.

Authors: Grace Glynn, UVM
Eric Hagen, UVM
Meridith Naughton, UVM

The newly acquired Richmond Town Forest (428 acres), lying south of the town center and east of Route 2, adds to the already conserved 10,000-acre Chittenden Uplands forest. A town forest sub-committee was formed to oversee how the town forest should be used and two potentially conflicting interests of citizens dominated: mountain biking and wildlife protection. We (graduate students in the Field Naturalist Program) were asked to inventory the property this autumn and to assess the likely effects of a proposed trail system on the Forest's wildlife. Using field surveys, soil surveys, geology maps, and aerial photographs, we mapped the Forest and found significant natural communities including dry oak forests, seepage forest, and vernal pools. We also surveyed wildlife habitat in the Forest, focusing on forest structure, species composition, fruit and nut production, successional stage, and likely deer wintering yards. Of particular interest were use (or likely use) of the forest by black bear, bobcat, fisher and white-tailed deer. From our collective data sets, game camera footage, talking with hunters and other users of the property, and from consulting past research on the property, we identified the location of wildlife "hotspots." We superimposed the proposed trail system on our map of wildlife hotspots and interpreted the potential impact on wildlife use in each specific location. The approach we employed, and how it could be used elsewhere, will be discussed.

Authors: Kristen Switzer, University of Vermont
Anthony D'Amato, University of Vermont
Peter Clark, University of Vermont

The impacts of climate change on global ecosystems are becoming increasingly clear. Research consistently shows increasing global temperatures are affecting biodiversity, vegetation dynamics, oceans, and important environmental processes. This study examines how climate has influenced tree growth in northern Vermont over the last 100 years for three tree species, Quercus rubra, Pinus strobus, and Tsuga canadensis, in an attempt to understand how these species might respond to expected future shifts in temperature and precipitation. Increment tree cores for these species were collected in Jericho Research Forest and response function analysis was used to examine how temperature and precipitation patterns have affected their growth in this region of Vermont. The importance of precipitation and temperature in driving past growth varied between species. Precipitation only affected Quercus rubra growth, with strong positive correlations between growth rates and precipitation in June and July. Temperature was more important to the two conifer species examined (Pinus strobus and Tsuga canadensis), with the strongest correlations being negative correlations between growth and June temperature. Pinus strobus growth was also negatively correlated with October temperatures, whereas Tsuga canadensis growth was negatively correlated with the temperatures in May, July, and August. These results highlight the importance of diverse species forests in conferring resilience to future climate change, as these represent a range of potential climate responses and sensitivities. Findings indicate Pinus strobus and Tsuga canadensis may be most vulnerable to changes in future temperature regimes, particularly shifts towards warmer temperatures, whereas Quercus rubra demonstrated greater moisture sensitivity. Maintaining mixtures of these and other species may be an effective management strategy for ensuring a wide range of climate responses are present across the landscape. Future work on a wider range of sites and species will be critical for expanding the results of this study to the broader landscape of Vermont to inform conservation efforts and identify vulnerable trees species.

Authors: Emma Sass, University of Vermont
Anthony D'Amato, University of Vermont
Paul Catanzaro, University of Massachusetts

Late-successional forest is relatively uncommon across the New England landscape, but late-successional characteristics such as higher coarse woody debris (CWD) levels, diversity in tree species and sizes, and large trees are common management objectives. Patch selection using 0.12-ha openings was applied to a second-growth northern hardwood forest in western Massachusetts in 2007 in conjunction with different methods of increasing late-successional traits, including within-patch legacy tree retention and CWD creation. After 10 years, all of the harvested treatments had higher sapling density than the control (unharvested) plots. While there was no difference in sapling species diversity across treatments, yellow and black birch sapling densities were higher in the harvested plots. Mortality rate of legacy trees remained low across the measurement period at 2.0%, and growth of legacy trees averaged 0.004 m2/year. CWD levels remained significantly higher in patches with intentionally created downed wood. Combining larger group openings with structural retention may serve to increase structural diversity while also recruiting a diversity of tree species on sites with a high American beech component.

Authors: Shelly Rayback, UVM
Alexandra Kosiba, FEMC
James Duncan, FEMC
Paul Schaberg, USDA Forest Service
Christopher Hansen, USDA Forest Service & UVM
Paula Murakami, USDA Forest Service
Gary Hawley, UVM
Jennifer Pontius, USDA Forest Service & UVM
Rebecca Stern, UVM

In the context of a rapidly changing environment, there is an increasing need for large data networks to answer pressing questions and respond to new research priorities that span broad spatial and long temporal scales. The DendroEcological Network (DEN) is a collaboration among FEMC, University of Vermont and the USDA Forest Service to bring together tree ring and associated ecological data from sites across the northeastern forest. The study of tree rings and their associated metadata facilitate monitoring of long-term trends and annual conditions and link these to the physical, chemical and biological components of the forest ecosystem. The DEN provides an open centralized cyberinfrastructure for the discovery, exploration and sharing of dendroecological data by researchers, forest managers and the public for investigations of the past, present and future health of our forests and their management. This high quality and reliable network also multiplies the scientific value of an individual's research effort by facilitating greater discoverability and expansion of that data beyond its original purpose. For example, the ability to investigate ecological processes at different temporal and spatial scales is needed as certain dynamics are only interpretable in the context of larger scale and longer term biogeographical or climatic processes. We present snapshots of our work on red spruce recovery as an example of the power of this data network and suggest other lines of investigation and exploration that could be followed.

Authors: Spencer Roberge Mr., Student from Saint Michael's College
Melanie George Ms., Student from Saint Michael's College
Connor Dunne Mr., Student from Saint Michael's College
Declan McCabe Prof., Biology Department Chair and Associate Professor of Biology of Saint Michael's College

Our focus with this project was to compare the abundance and richness of invertebrates in Lake Champlain's St. Albans Bay, Inland Sea, and Missisquoi Bay. Invertebrate populations make up much of the diversity within lake ecosystems. Determining the number of benthic invertebrate species in a lake system is one metric of overall ecosystem health. We used ponar dredges and a box corer to sample the Inland Sea (N = 229), Missisquoi Bay (N = 334) and Saint Alban's Bay (N = 129). A comparisons abundance and richness among the three sites were performed using single factor ANOVAs. I hypothesized that deeper bodies of water would have an overall lower number of diversity compared to shallower and potentially more productive habitats. I found that the data supported my hypothesis as the St. Albans Bay and Missisquoi Bay samples had higher species richness. The Inland Sea of Lake Champlain had a high abundance, but low richness which may well be explained by lack of light in the deeper benthic zone. The deeper water Inland Sea samples were dominated by zebra mussel and midges and there was reduced abundance of benthic periphyton grazers such as snails that tended to be common in Missisquoi Bay.

Authors: James Duncan, UVM, RSENR, FEMC
Emma Tait, UVM, RSENR, FEMC
Alexandra Kosiba, UVM, RSENR, FEMC
Jennifer Pontius, UVM, RSENR, USFS Northern Research Station, FEMC

The Northeastern Forest Health Atlas (NEFHA) is a compilation of contemporary and historic aerial survey data (1918-2016) and field datasets related to forest disturbance and health in the Northeastern US. NEFHA provides information on short- and long-term changes in forest health and disturbance to researchers, managers, policy makers, and the general public. The online NEFHA interface provides dynamic maps of forest damage collected from aerial surveys, as well as links to related forest health research. NEFHA users can filter by damage agent, damage type, state, and year, as well as view graphs and tables of disturbance patterns over time and download maps and data.

Authors: James Duncan, UVM, RSENR, FEMC
Alexandra Kosiba, UVM, RSENR, FEMC
Mike Finnegan, UVM, RSENR, FEMC
John Truong, UVM, RSENR, FEMC

The Northeast Forest Fragmentation Information Network (FragNet) is an information clearinghouse containing resources aimed at understanding and addressing forest fragmentation and parcelization in the northeastern US. FragNet makes it easier for researchers, land managers, policy makers, academics, and local governments to find and access all the available information on fragmentation occurring within their area of interest. In the initial pilot phase of FragNet, we focused on resources pertaining to the state of Vermont. With the initial framework built, we expanded FragNet to include other states in the northeast. Currently, FragNet houses nearly 300 resources that can be searched by type, topic, or primary purpose, as well as by location and time frame, facilitating access to information related to forest fragmentation.

Authors: Heather Ewing, Vermont Department of Forests, Parks & Recreation
Lisa Thornton, Vermont Department of Forests, Parks & Recreation
Lina Swislocki, Vermont Department of Forests, Parks & Recreation

Being able to maintain resilient forests in the Northeast depends on addressing one of the most serious threats to natural ecosystems--invasive species. Climate change will continue to give these non-native species a competitive advantage and it is critical to put forth efforts to control their spread. In Vermont, the Department of Forests, Parks & Recreation is working to create model approaches for non-native invasive plant management prioritization of imperiled and sensitive areas, and for building capacity through a newly launched volunteer network and expansion of ongoing volunteer efforts.

Authors: Jennifer Pontius, University of Vermont RSENR , USFS Northern Research Station and Forest Ecosystem Monitoring Cooperative
James Duncan, University of Vermont RSENR and Forest Ecosystem Monitoring Cooperative
Alexandra Kosiba, University of Vermont RSENR and Forest Ecosystem Monitoring Cooperative

Ecological indicators are becoming commonly utilized to describe and monitor the status of complex ecosystems. Many policy-makers, educators, and managers have expressed a need for a comprehensive, yet dynamic assessment of the condition of the Vermont's forests. Recognizing this need, in 2015 a working group convened to identify key metrics and data aggregation methods for a data-driven group of indicators for Vermont's forests. The FEMC has led the development of the data aggregation and synthesis tool that resulted from this design effort, The Forest Indicators Dashboard. This tool is a dynamic, online, quantitative, systems-based assessment of the current status and long-term trends of Vermont’s forested ecosystem.The resulting indicators provide a more holistic view of the structure, function, and services provided by forest ecosystems.

Authors: Tony D'Amato, Rubenstein School of Environment and Natural Resources, University of Vermont
Chris Swanston, Northern Institute of Applied Climate Science, US Forest Service
Todd Ontl, USDA Northern Forests Hub and Northern Institute of Applied Climate Science

Forests are a defining landscape feature across New England and northern New York, covering more than 40 million acres from the coast of the Atlantic Ocean to the peaks of the Appalachian Mountains. The changing climate is altering the region's forests, and the foresters and other natural resource professionals working to keep the region's forest ecosystems healthy and productive are increasingly considering climate change in their work. The New England Climate Change Response Framework, a collective effort among dozens of scientists and natural resource professionals, has produced a new report that summarizes the best available information about climate change and regional forests based on published research, ecosystem models, and manager expertise. New projections of forest change from three forest impacts models--the Climate Change Tree Atlas, Linkages, and LANDIS PRO--were combined with a review of recent literature to understand the potential for forest change during the next century under different climate scenarios. An expert panel of research scientists and forest practitioners then worked together to consider this information, as well as their personal experience and expertise on local ecosystems, to assess the vulnerability of eight forest communities present across the region. Montane spruce-fir, low-elevation spruce-fir, and lowland mixed conifer forests were determined to be the most vulnerable to climate change. Lowland hardwood and riparian forests were assessed as being moderately vulnerable. Northern hardwood, transition hardwood, central hardwood-pine, and pitch-pine scrub oak forests were rated as having lower vulnerability to projected changes in climate. Projected changes in climate and their associated impacts and vulnerabilities will have important implications for ecologically and economically valuable forest types, forest-dependent wildlife and plants, recreation, and long-term natural resource planning.

Authors: Dylan O'Leary, The Nature Conservancy-Vermont Chapter

Golden-winged warblers (Vermivora chrysoptera) have sustained sharp population declines over the last 50 years and are listed as Near Threatened by the International Union for Conservation of Nature. Habitat loss from urban sprawl, aging forests and destruction of their wintering grounds have reduced their numbers and shifted their range northwest making VT part of the very eastern edge of their existence. Helen W. Buckner Memorial Preserve at Bald Mountain in West Haven, VT sustains the largest population in the northeast of these dynamic little birds, due in large part to the agricultural legacy of the area. State endangered timber rattlesnakes (Crotalus horridus), state threatened eastern ratsnakes (Pantherophis alleghaniensis), and the eastern ribbon snake (Thamnophis sauritus), a species of special concern, have all etched out an existence here as well and rely heavily upon the abundance of leopard frogs (Lithobates pipiens)in the fields surrounding the talus slopes. The Vermont Chapter of The Nature Conservancy has teamed up with Audubon Vermont and Green Mountain College in two simultaneous efforts to utilize old agricultural fields to restore ideal habitat for these imperiled species. Our management plan with Audubon includes extensive brush clearing via mechanical and chemical means, protocol testing to develop efficient ways of monitoring population changes, deployment of geolocators to elucidate migration habits, and community stewardship in the form of an annual "Warbler Blitz". New this year, in partnership with Green Mountain College, we are testing different mowing patterns to promote herp habitat. They will coincide with the warbler management and the monitoring of amphibian population changes via drift fences. We are also putting college students to work, constructing wooden structures or 'snake hotels' for snakes to congregate and bask in, putting us at the cutting edge of herp hospitality.

Authors: Jennifer Pontius, UVM and USFS NRS
David Gudex-Cross, , UVM RSENR
Adams Alison, UVM Gund

Improvements in both sensor and computing technologies has allowed researchers to more closely examine historical changes in forest structure and function across the forested landscape. Here we highlight the findings of three recent papers that build off a 30+ year archive of satellite imagery to 1) quantify the extent and pattern of changes in forest cover, 2) track changes in tree species abundance across the landscape, and 3) document patterns in phenological events such as spring bud burst and fall senescence. Remote sensing products like these are essential to understand the potential drivers of change in the region's forests, identify locations or forest types particularly at risk, and inform the sustainable management of this critical resource at a time of rapid environmental change.