Publication Date
5-2024
Date of Final Oral Examination (Defense)
3-7-2024
Type of Culminating Activity
Thesis
Degree Title
Master of Science in Raptor Biology
Department Filter
Biology
Department
Biological Sciences
Supervisory Committee Chair
Julie A. Heath, Ph.D.
Supervisory Committee Member
T. Trevor Caughlin, Ph.D.
Supervisory Committee Member
Peter J. Olsoy, Ph.D.
Abstract
Migration is an energetically expensive and risky event in the life cycles of many organisms, and migration impacts survival and reproductive success through direct and carry-over effects. The timing of migration departure from the summer breeding grounds is important for determining the probability of survival and physical condition upon arrival at wintering sites. Many internal and external factors contribute to departure timing. It is important to study these factors across species, populations, and individuals to determine which traits and conditions are most important for shaping departure timing and its variability. Improving our understanding of the factors that affect organisms’ phenological cycles, particularly the understudied events in those cycles, is necessary to predict how populations, and the communities they are a part of, may be affected by environmental change. I studied the life history correlates and weather conditions associated with the timing of departure for North American raptor species.
In the first chapter, I used data from eBird to calculate spatially-explicit autumn departure timing for 15 migratory raptor species across the United States and Canada from 2011 to 2021. Using these departure dates as a response variable and accounting for the uncertainty involved in these estimates, I then examined the relative importance of five life history traits and latitude in explaining departure timing between species and the effect of three life history traits on variation in departure timing within species across space and over time. I found that an interaction between migration distance and latitude affected departure timing. The negative effect of latitude (northern birds departing before southern birds) was stronger in short-distance migrants compared to long-distance migrants. Further, socially migrating species tended to depart earlier than species that migrate alone, and larger-bodied species tended to depart later than smaller species. Finally, long-distance migrants, diet-specialists, and social migrants had more consistent departure timing compared to short-distance migrants, diet generalists, and solitary migrants who were more variable in timing.
In the second chapter, I selected the four raptor species (Broad-winged Hawk, Osprey, Swainson’s Hawk, and Turkey Vulture) with the greatest eBird data availability and assessed their departure timing within a latitudinal band across the northern US from 2002 to 2021. Using weather data from Daymet and a sliding window analysis, I determined the most likely periods of sensitivity to four weather variables for each species' departure timing. I then combined these season-specific weather variables to build a full weather model for each species. Maximum temperature was important for determining the departure timing of all species, but the direction of effect varied (some advancing or delaying departure) depending on the time of year and species. Minimum temperature and precipitation was important for determining the departure time of several species, and snow-water-equivalent only explained the departure of Broad-winged Hawks. Finally, I used the full weather models for each species and data from NA-CORDEX to forecast departure timing of all four species to 2075. The forecast analysis showed that over the next 50 years, Swainson’s Hawks will advance their departure timing (depart earlier in the year) and Turkey Vultures will delay departure (depart later in the year). There were no significant temporal trends for the timing of Broad-winged Hawk autumn migration, and Osprey departure timing is expected to advance very slightly.
Combined, these analyses provide insight into the biological and environmental factors affecting raptor autumn migration timing in North America. This information furthers our understanding of the relationships between life history traits and departure timing and provides new insight into factors associated with annual variation in departure timing, which may underlie vulnerability to changing environmental conditions. Additionally, it identifies unique environmental factors related to the timing of autumn departure for four common species and provides estimates of future changes in an important part of their full annual cycles.
DOI
https://doi.org/10.18122/td.2215.boisestate
Recommended Citation
Honkomp, Nora R., "Biological and Environmental Factors Associated with the Autumn Migration Timing of North American Raptors" (2024). Boise State University Theses and Dissertations. 2215.
https://doi.org/10.18122/td.2215.boisestate
