Your search keyword '"Newby, Jesse R."' showing total 6 results

1. SPATIAL AND TEMPORAL HETEROGENEITY IN THERMAL CONDITIONS FOR WILDLIFE

Author

DeCesare, Nicholas J., Harris, Richard. B., Newby, Jesse R., and Peterson, Collin J.

Subjects

Evolution -- Analysis, Population biology -- Analysis, Sensors -- Analysis, Radiation -- Analysis, Moose -- Analysis, Ecology -- Analysis, Climatic changes -- Analysis, General interest, News, opinion and commentary

Abstract

Temperature is an important component of climatic conditions that drive animal evolution, niche space, and life history traits. We used field-deployed temperature sensors and generalized linear mixed-effects models to quantify the spatiotemporal variation of ambient temperatures in three study areas of western Montana, in support of concurrent studies of moose ecology and population dynamics. We found substantial potential for thermal refuge for moose; temperature ranges observed simultaneously among sites within study areas averaged 7.0[degrees]C during summer and 6.1[degrees]C during winter. We considered 6 site variables hypothesized to affect local temperatures (elevation, topographic position, aspect, land cover type, forest canopy cover, and the interaction of land cover and solar radiation), and all contributed to model performance. However, the direction and magnitude of effects varied in a cyclic fashion during the 24-hour diel cycle, and in many cases, exhibited reversed effects between day and night. Although spatial heterogeneity in temperature during summer was only slightly higher than during winter, our ability to explain such pattern was much better during summer (average [R.sup.2] = 0.51-0.56) than during winter (average [R.sup.2] = 0.09-0.23). We encourage researchers and managers to explore field collection and spatiotemporal modeling of temperature sensor data for cost-effect description of thermal environments for wildlife in local settings. Key words: Alces alces, ambient temperature, climate change, diel cycle, habitat, iButton, Montana, moose, spatial, summer, thermal cover, winter, Temperature is an important component of climatic conditions that drive animal evolution, niche space, and life history traits (Magnuson et al. 1979). Wildlife responses to variation in temperature can include [...]

Published

2023

2. Phylogeography of moose in western North America

Author

DeCesare, Nicholas J., Weckworth, Byron V., Pilgrim, Kristine L., Walker, Andrew B. D., Bergman, Eric J., Colson, Kassidy E., Corrigan, Rob, Harris, Richard B., Hebblewhite, Mark, Jesmer, Brett R., Newby, Jesse R., Smith, Jason R., Tether, Rob B., Thomas, Timothy P., and Schwartz, Michael K.

Published

2020

3. Warm places, warm years, and warm seasons increase parasitizing of moose by winter ticks.

Author

DeCesare, Nicholas J., Harris, Richard B., Atwood, M. Paul, Bergman, Eric J., Courtemanch, Alyson B., Cross, Paul C., Fralick, Gary L., Hersey, Kent R., Hurley, Mark A., Koser, Troy M., Levine, Rebecca L., Monteith, Kevin L., Newby, Jesse R., Peterson, Collin J., Robertson, Samuel, and Wise, Benjamin L.

Subjects

TICKS, MOOSE, LIFE cycles (Biology), WEATHER, ANIMAL populations, CLIMATE change & health, ANIMAL population density

Abstract

Observed links between parasites, such as ticks, and climate change have aroused concern for human health, wildlife population dynamics, and broader ecosystem effects. The one‐host life history of the winter tick (Dermacentor albipictus) links each annual cohort to environmental conditions during three specific time periods when they are predictably vulnerable: spring detachment from hosts, summer larval stage, and fall questing for hosts. We used mixed‐effects generalized linear models to investigate the drivers of tick loads carried by moose (Alces alces) relative to these time periods and across 750 moose, 10 years, and 16 study areas in the western United States. We tested for the effects of biotic factors (moose density, shared winter range, vegetation, migratory behavior) and weather conditions (temperature, snow, humidity) during each seasonal period when ticks are vulnerable and off‐host. We found that warm climatic regions, warm seasonal periods across multiple partitions of the annual tick life cycle, and warm years relative to long‐term averages each contributed to increased tick loads. We also found important effects of snow and other biotic factors such as host density and vegetation. Tick loads in the western United States were, on average, lower than those where tick‐related die‐offs in moose populations have occurred recently, but loads carried by some individuals may be sufficient to cause mortality. Lastly, we found interannual variation in tick loads to be most correlated with spring snowpack, suggesting this environmental component may have the highest potential to induce change in tick load dynamics in the immediate future of this region. [ABSTRACT FROM AUTHOR]

Published

2024

4. Human-caused mortality influences spatial population dynamics: Pumas in landscapes with varying mortality risks

Author

Newby, Jesse R., Scott Mills, L., Ruth, Toni K., Pletscher, Daniel H., Mitchell, Michael S., Quigley, Howard B., Murphy, Kerry M., and DeSimone, Rich

Published

2013

5. Phylogeography of moose in western North America

Author

DeCesare, Nicholas J, primary, Weckworth, Byron V, primary, Pilgrim, Kristine L, primary, Walker, Andrew B D, primary, Bergman, Eric J, primary, Colson, Kassidy E, primary, Corrigan, Rob, primary, Harris, Richard B, primary, Hebblewhite, Mark, primary, Jesmer, Brett R, primary, Newby, Jesse R, primary, Smith, Jason R, primary, Tether, Rob B, primary, Thomas, Timothy P, primary, and Schwartz, Michael K, primary

Published

2019

6. Calibrating minimum counts and catch‐per‐unit‐effort as indices of moose population trend

Author

DeCesare, Nicholas J., primary, Newby, Jesse R., additional, Boccadori, Vanna J., additional, Chilton‐Radandt, Tonya, additional, Thier, Tim, additional, Waltee, Dean, additional, Podruzny, Kevin, additional, and Gude, Justin A., additional

Published

2016