UUnniivveerrssiittyy ooff MMoonnttaannaa SScchhoollaarrWWoorrkkss aatt UUnniivveerrssiittyy ooff MMoonnttaannaa Graduate Student Theses, Dissertations, & Graduate School Professional Papers 2013 EEffffeeccttss ooff llooccaall aanndd llaannddssccaappee pprroocceesssseess oonn aanniimmaall ddiissttrriibbuuttiioonn aanndd aabbuunnddaannccee Aaron David Flesch University of Montana, Missoula Follow this and additional works at: https://scholarworks.umt.edu/etd Let us know how access to this document benefits you. RReeccoommmmeennddeedd CCiittaattiioonn Flesch, Aaron David, "Effects of local and landscape processes on animal distribution and abundance" (2013). Graduate Student Theses, Dissertations, & Professional Papers. 10749. https://scholarworks.umt.edu/etd/10749 This Dissertation is brought to you for free and open access by the Graduate School at ScholarWorks at University of Montana. It has been accepted for inclusion in Graduate Student Theses, Dissertations, & Professional Papers by an authorized administrator of ScholarWorks at University of Montana. For more information, please contact [email protected]. EFFECTS OF LOCAL AND LANDSCAPE PROCESSES ON ANIMAL DISTRIBUTION AND ABUNDANCE By AARON DAVID FLESCH B.A. Prescott College, Prescott, Arizona, 1995 M.S. University of Arizona, Tucson, Arizona, 2003 Dissertation presented in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Organismal Biology and Ecology The University of Montana Missoula, Montana Autumn 2013 Approved by: Sandy Ross, Dean of The Graduate School Graduate School Dr. Richard L. Hutto, Chair Organismal Biology and Ecology Dr. Winsor H. Lowe Organismal Biology and Ecology Dr. John L. Maron Organismal Biology and Ecology Dr. Mark Hebblewhite Wildlife Biology Program Dr. Paul M. Lukacs Wildlife Biology Program UMI Number: 3611855 All rights reserved INFORMATION TO ALL USERS The quality of this reproduction is dependent upon the quality of the copy submitted. In the unlikely event that the author did not send a complete manuscript and there are missing pages, these will be noted. Also, if material had to be removed, a note will indicate the deletion. UMI 3611855 Published by ProQuest LLC (2014). Copyright in the Dissertation held by the Author. Microform Edition © ProQuest LLC. All rights reserved. This work is protected against unauthorized copying under Title 17, United States Code ProQuest LLC. 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, MI 48106 - 1346 © COPYRIGHT by Aaron David Flesch 2013 All Rights Reserved ii Flesch, Aaron D., Ph.D., 2013 Organismal Biology and Ecology Effects of local and landscape processes on animal distribution and abundance Advisor: Richard L. Hutto. Ph.D. Abstract: Investigations of processes that drive animal distribution and abundance are often approached at one of two different scales and therefore focus on different processes. At local scales, animals are thought to select home ranges or territory patches in an ideal manner by occupying them in order of their fitness potential, but a variety of processes can decouple choices from their fitness consequences and create non-ideal patterns of distribution. At landscape scales, the spatial arrangement of habitat patches and their size and isolation are thought to influence distribution patterns because extinction probability declines with increasing patch area and colonization probability declines with increasing patch isolation. Although understanding the relative effects of local and landscape processes on distribution is essential for conservation, very few studies have explicitly considered the fitness potential or quality of habitat when doing so, especially at small scales relevant to the behavioral choices of individuals. I integrated behavioral and landscape approaches for understanding distribution by assessing the relative and combined effects of habitat quality at territory-specific scales and the effects of habitat amount, habitat configuration, and matrix structure at landscape scales on long-term occupancy dynamics of Ferruginous Pygmy-Owls over 12 years. To quantify habitat quality, I considered the estimated additive and interactive effects of habitat resources, stochastic factors (e.g., weather), and conspecific density on reproductive output based on extensive demographic monitoring over 10 years in the same territory patches. Habitat resources explained a much greater proportion of variation in reproductive output than weather or conspecifics, but realized habitat quality was best described by the interactive effects of all these factors. High-quality habitats buffered the negative effects of conspecifics and amplified the benefits of favorable weather, but did not buffer the disadvantages of harsh weather. The positive, density-independent effects of favorable weather at low conspecific densities were offset by intraspecific competition at high densities. Habitat quality had greater effects than landscape processes on patch occupancy dynamics, and its effects were best described by interactions among habitat resources, weather, and conspecifics. Nonetheless landscape factors also had important effects: habitat amount had greater effects than habitat fragmentation or matrix structure, effects that were either positive or negative depending on local habitat quality. Although metapopulation theory is the dominant paradigm upon which many conservation strategies are based, improving local habitat quality may yield greater returns, especially when the surrounding landscape context is considered. iii ACKNOWLEDGEMENTS This dissertation is the culmination of 12 years of demanding but extremely rewarding field work in the Sonoran Desert region of northwest Mexico. Despite its challenges, working in Mexico has taught me a great deal about ecology while providing a rare opportunity to explore a region few know well. This effort would not have been possible without the support and commitment of many individuals and agencies. I am especially grateful to my friend and field companion, Sky Jacobs for his help during the majority of field seasons since 2000. Sky’s knowledge, skill, and dedication to field work allowed efficient data collection across a large region in challenging field conditions and greatly enhanced my experience during this effort. I am also grateful to the many technicians that assisted me in the field. I thank my advisor Dick Hutto for believing in me, for his enthusiastic participation in many thoughtful conversations regarding the conceptual foundations of my work, and for his help and patience in reviewing and commenting on my writing. Dick has been a great inspiration to me on many levels, intellectually, personally, and for his always positive demeanor. I am also grateful to my advisory committee, Mark Hebblewhite, Paul Lukacs, John Maron, Winsor Lowe, and Elizabeth Crone for their time and constructive feedback over the years, and for commenting on my writing. I am especially grateful to John Maron for providing feedback on Chapter 2, which improved its quality and readability. Although he was the last person to join my committee, I thank Paul Lukacs for his time, help, and suggestions during the later stages of this process and for advice on analyses and interpretation. I thank Winsor Lowe for his time in implementing my comprehensive exams and for comments related to metapopulation concepts in Chapter 3. iv Consistency of effort and long-term commitment are required to collect data over long time frames. My efforts would not have been possible without the support of numerous agencies, organizations, and individuals. They include the U.S. National Park Service, Desert Southwest Cooperative Ecosystem Studies Unit, Tucson Audubon Society, Arizona Department of Transportation, T & E Inc., Defenders of Wildlife, Center for Biological Diversity, Sonoran Joint Venture, U.S. Fish and Wildlife Service, Arizona Zoological Society, Global Owl Project, Rincon and Grand Canyon chapters of the Sierra Club, and Chiyoda Raft. I am especially grateful to the many non-profit organizations that supported my efforts during times when public support was unavailable. Their commitment to science-based management and conservation is a great motivating force. Specifically, I thank Matt Clark of Defenders of Wildlife and Paul Green of Tucson Audubon Society for support during later years, and Tom Wootten of T&E Inc. for providing small but critical support during middle years of the study. I thank Larry Norris and Peter Holm of the U.S. National Park Service for support during several field seasons. Finally, I thank The University of Montana Graduate School and those that contributed generously to the scholarships I was awarded. They include the Bertha Morton Graduate Scholarship (2008-2009), Clancy Gordon Environmental Scholarship (2010-2011), Bertha Morton Graduate Fellowship (2011-2012), and the important Besancon Graduate Fellowship for Science, Technology, Engineering, and Mathematics (2011-2012). Numerous others helped with data entry and acquisition, analyses, logistical support, and permits. I thank Luke Felig, Anthony Smith, Josh Goldberg, and Megan Girsch for assistance in the lab. I thank Alan Swanson for his help and expertise in using R. For v logistical support, I thank Eduardo Lopez Saavedra of Instituto del Medio Ambiente y el Desarrollo Sustentable del Estado de Sonora, Jaqueline Garcia Hernandez of Centro de Investigación en Alimentación y Desarrollo, José Fernando Villaseñor Gómez, Universidad Michoacana de San Nicolás de Hidalgo. I thank Gilberto Lagarda Vásquez of Comisión Nacional de Auga for weather data from Mexican stations and Peter Holm for data on lizards and weather in Organ Pipe Cactus National Monument. I thank Willem J. D. van Leeuwen and Kyle Hartfield of the Arizona Remote Sensing Center, School of Natural Resources and the Environment at University of Arizona for assistance measuring large-scale environmental factors using remote-sensing techniques. Administration of my projects was facilitated largely by the University of Arizona, School of Natural Resources and the Environment. I am especially grateful to Cecily Westphal and Kathi Moroz for administrative support and the entire office staff of the School of Natural Resources and the Environment for help with travel, logistics, and grant administration. I thank Robert Steidl, R. William Mannan, and William Shaw for suggestions during early years this work. At The University of Montana, I thank Teresa Daniels of the Division of Biological Sciences for administrative support, Jay Bruns for computer support, and the entire office staff of the Division of Biological Sciences. I am very grateful to Megan Fylling, Kristina Smucker, and Anna Noson of the Avian Science Center for their help, advice, and encouragement over the years, and for providing a fun and congenial environment in my lab. I thank Erick and Anne Greene for making the second floor of the Health Sciences building a great place to work. Finally, I thank the entire community of graduate students vi and faculty of the Organismal Biology and Ecology program for making OBE a great place to study. This work was made possible by the people and landowners of Sonora, Mexico. Their generosity, hospitality, and goodwill across the great state of Sonora facilitated work in many remote and wild areas of the borderlands, virtually all of which was on private lands and completed without incident. Most importantly, I thank my family and friends. My mom, Cathy Slatas, encouraged me to follow my passion for field biology and to believe in myself. My grandfather, Benjamin M. Chameides, encouraged me to explore the outdoors and to do what I love, and this effort is very much in the spirit of his counsel. My aunt, Harriet Spiegelman, my grandmother Dorothy Chameides, and my cousins Scott and Todd Spiegelman have always been great sources of love and support. I also thank my friend Mac Hudson for accompanying me on field trips, providing me with a home in Tucson, and for his enduring friendship. Lastly, I thank my friends Glenn, Alan, Dylan, Chris, Heath, Kyla, Claire, Amy, Deana, Jennifer, and others for their support and companionship over the years. Thank you all for being great sources of strength and inspiration. vii TABLE OF CONTENTS ACKNOWLEDGEMENTS ............................................................................................... iv TABLE OF CONTENTS ................................................................................................. viii LIST OF TABLES ............................................................................................................ xii LIST OF FIGURES ......................................................................................................... xvi PREFACE ....................................................................................................................... xxii CHAPTER 1 SPATIOTEMPORAL TRENDS AND DRIVERS OF POPULATION DYNAMICS IN A DECLINING NEOTROPICAL OWL ................................................................................ 1 Abstract ............................................................................................................................... 2 INTRODUCTION .............................................................................................................. 3 METHODS ......................................................................................................................... 6 Sampling and survey design ......................................................................................... 6 Trend analyses .............................................................................................................. 7 Environmental drivers ................................................................................................... 9 RESULTS ......................................................................................................................... 11 Trends and variances................................................................................................... 11 Environmental drivers ................................................................................................. 12 DISCUSSION ................................................................................................................... 13 ACKNOWLEDGEMENTS .............................................................................................. 19 LITERATURE CITED ..................................................................................................... 19 SUPPLEMENTAL MATERIAL ...................................................................................... 24 CHAPTER 2 SPATIAL, TEMPORAL, AND DENSITY-DEPENDENT COMPONENTS OF HABITAT QUALITY FOR FERRUGINOUS PYGMY-OWLS .................................... 35 Abstract ............................................................................................................................. 36 INTRODUCTION ............................................................................................................ 37 STUDY SYSTEM ............................................................................................................ 43 viii
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