Landscape Partnership Resources Library
Strategy Implementation
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Conclusions
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Species and Location Prioritization
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Comparing Alternative Management Approaches
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Alternative Management Approaches
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Goals and Objectives
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Strategy Development
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Assumptions
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Species and Threats
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Introduction and Geographic Scope
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Purpose
From the Imperiled Aquatic Species Conservation Strategy for the Upper Tennessee River Basin.
Cave/Karst Resources Across the Appalachian LCC: A Visual Guide to Results PDF
This visual guide documents 18 months of work gathering and analyzing data on caves and karst resources in the Appalachian LCC. The maps and files provide a comprehensive overview of data available for examining relationships between environmental factors and biological diversity and distribution within karst areas in the region. This visual survey is intended to be a guide to what the researchers have accomplished, and a guide to what new questions and results would be interesting to end-users.
Guidelines for Using the NatureServe Climate Change Vulnerability Index
Motivated by the need to rapidly assess the vulnerability of species to climate change, NatureServe developed a Climate Change Vulnerability Index. The Index uses a scoring system that integrates a species’ predicted exposure to climate change within an area and three sets of factors associated with climate change sensitivity, each supported by published studies: 1) indirect exposure to climate change, 2) species-specific sensitivity and adaptive capacity factors and 3) documented response to climate change. Our primary goal for the Index is to provide valuable input for key planning documents, such as revisions of state wildlife action plans, to allow consideration of climate change impacts together with other stressors. We also hope this tool will help land managers develop and prioritize strategies for climate change adaptation that lead to actions that increase the resilience of species to climate change.
Guidelines for Using the NatureServe Climate Change Vulnerability Index
Motivated by the need to rapidly assess the vulnerability of species to climate change, NatureServe developed a Climate Change Vulnerability Index. The Index uses a scoring system that integrates a species’ predicted exposure to climate change within an area and three sets of factors associated with climate change sensitivity, each supported by published studies: 1) indirect exposure to climate change, 2) species-specific sensitivity and adaptive capacity factors and 3) documented response to climate change. Our primary goal for the Index is to provide valuable input for key planning documents, such as revisions of state wildlife action plans, to allow consideration of climate change impacts together with other stressors. We also hope this tool will help land managers develop and prioritize strategies for climate change adaptation that lead to actions that increase the resilience of species to climate change.
Diffusion into new markets: evolving customer segments in the solar photovoltaics market
The US residential solar market is growing quickly, and as solar adoption diffuses into new populations, later adopters may differ significantly from earlier ones. Using a unique household-level survey dataset including 1234 adopters and 790 non-adopters from San Diego County, California, we explore differences in attitudinal and socio-economic factors for three groups: (i) adopters and non- adopters; (ii) early and more recent adopters; (iii) consumers adopting via buying or leasing. Our results suggest that adopters overall have higher incomes, are more educated, live in larger homes, and expect to stay in their homes for longer than their non-adopting peers. They also differ in their expectations of electricity retail rate changes and the impact solar could have on their home resale value. When examining differences between early and more recent adopters, we find that recent adopters are more representative of general homeowners and more politically moderate. They are also increasingly installing solar to protect against future electricity price increases and to lower electricity costs as opposed to adopting strictly for environmental reasons. Furthermore, more recent adopters differ significantly from earlier adopters in the situations that prompted them to adopt. The findings demonstrate how solar markets are evolving, reflecting changes in the underlying drivers of consumer adoption as well as innovative solar marketing strategies.
Seasonal weather patterns drive population vital rates and persistence in a stream fish
Here, we investigated effects of seasonal air temperature and precipitation (fall, winter, and spring) on survival and recruitment of brook trout (Salvelinus fontinalis) at a broad spatial scale using a novel stage-structured population model. The data were a 15-year record of brook trout abundance from 72 sites distributed across a 170-km-long mountain range in Shenandoah National Park, Virginia, USA. Population vital rates responded differently to weather and site-specific conditions. Specifically, young-of-year survival was most strongly affected by spring temperature, adult survival by elevation and per-capita recruitment by winter precipitation. Low fall precipitation and high winter precipitation, the latter of which is predicted to increase under climate change for the study region, had the strongest negative effects on trout populations. Simulations show that trout abundance could be greatly reduced under constant high winter precipitation, consistent with the expected effects of gravel-scouring flows on eggs and newly hatched individuals. However, high-elevation sites would be less vulnerable to local extinction because they supported higher adult survival. Furthermore, the majority of brook trout populations are projected to persist if high winter precipitation occurs only intermittently (≤3 of 5 years) due to density-dependent recruitment. Variable drivers of vital rates should be commonly found in animal populations characterized by ontogenetic changes in habitat, and such stage-structured effects may increase population persistence to changing climate by not affecting all life stages simultaneously. Yet, our results also demonstrate that weather patterns during seemingly less consequential seasons (e.g., winter precipitation) can have major impacts on animal population dynamics.
Projected increase in lightning strikes in the United States due to global warming
Lightning plays an important role in atmospheric chemistry and in the initiation of wildfires, but the impact of global warming on lightning rates is poorly constrained. Here we propose that the lightning flash rate is proportional to the convective available potential energy (CAPE) times the precipitation rate. Using observations, the product of CAPE and precipitation explains 77% of the variance in the time series of total cloud-to- ground lightning flashes over the contiguous United States (CONUS). Storms convert CAPE times precipitated water mass to discharged lightning energy with an efficiency of 1%. When this proxy is applied to 11 climate models, CONUS lightning strikes are predictedto increase 12 +_ 5% per degree Celsius of global warming and about 50% over this century
The future of farming: return to roots?
Large scale farming would be more sustainable if major crop plants lived for years and built deep root systems.
Sustainable Development under Population Pressure: Lessons from Developed Land Consumption in the Conterminous U.S.
Population growth will result in a significant anthropogenic environmental change worldwide through increases in developed land (DL) consumption. DL consumption is an important environmental and socioeconomic process affecting humans and ecosystems. Attention has been given to DL modeling inside highly populated cities. However, modeling DL consump- tion should expand to non-metropolitan areas where arguably the environmental consequences are more significant. Here, we study all counties within the conterminous U.S. and based on satellite-derived product (National Land Cover Dataset 2001) we calculate the associated DL for each county. By using county population data from the 2000 census we present a comparative study on DL consumption and we propose a model linking population with expected DL consumption. Results indicate distinct geographic patterns of comparatively low and high consuming counties moving from east to west. We also demonstrate that the relationship of DL consumption with population is mostly linear, altering the notion that expected population growth will have lower DL consumption if added in counties with larger population. Added DL consumption is independent of a county’s starting population and only dependent on whether the county belongs to a Metropolitan Statistical Area (MSA). In the overlapping MSA and non-MSA population range there is also a constant DL efficiency gain of approximately 20km2 for a given population for MSA counties which suggests that transitioning from rural to urban counties has significantly higher benefits in lower populations. In addition, we analyze the socioeconomic composition of counties with extremely high or low DL consumption. High DL consumption counties have statistically lower Black/ African American population, higher poverty rate and lower income per capita than average in both NMSA and MSA counties. Our analysis offers a baseline to investigate further land consumption strategies in anticipation of growing population pressures.
The cold-water climate shield: delineating refugia for preserving salmonid fishes through the 21st century
The distribution and future fate of ectothermic organisms in a warming world will be dictated by thermal-scapes across landscapes. That is particularly true for stream fishes and cold-water species like trout, salmon, and char that are already constrained to high elevations and latitudes. The extreme climates in those environments also preclude invasions by most non-native species, so identifying especially cold habitats capable of absorbing future climate change while still supporting native populations would highlight important refugia. By coupling crowd-sourced biological datasets with high-resolution stream temperature scenarios, we delineate network refugia across >250 000 stream km in the Northern Rocky Mountains for two native salmonids—bull trout (BT) and cutthroat trout (CT). Under both moderate and extreme climate change scenarios, refugia with high probabilities of trout population occupancy (>0.9) were predicted to exist (33–68 BT refugia; 917–1425 CT refugia). Most refugia are on public lands (>90%) where few currently have protected status in National Parks or Wilderness Areas (<15%). Forecasts of refuge locations could enable protection of key watersheds and provide a foundation for climate smart planning of conservation networks. Using cold water as a ‘climate shield’ is generalizable to other species and geographic areas because it has a strong physiological basis, relies on nationally available geospatial data, and mines existing biological datasets. Importantly, the approach creates a framework to integrate data contributed by many individuals and resource agencies, and a process that strengthens the collaborative and social networks needed to preserve many cold-water fish populations through the 21st century.
