Daniel Esler, Ph.D.
Dan is a Research Wildlife Biologist with the Alaska Science Center and leads the Nearshore Marine Ecosystem Research Program. His work focuses on nearshore marine monitoring, drivers of variation in nearshore systems, sea duck ecology and conservation, and program management.
Professional Experience
2013 - Present Research Wildlife Biologist, USGS Alaska Science Center
2001 - 2013 Research Scientist, Centre for Wildlife Ecology, Simon Fraser University, Delta, British Columbia
1990 - 2001 Research Wildlife Biologist, USGS/US Fish and Wildlife Service, Alaska Biological Science Center/Alaska Fish and Wildlife Research Center, Anchorage, Alaska
1989 - 1990 Biological Technician, US Fish and Wildlife Service, Alaska Fish and Wildlife Research Center, Anchorage, Alaska
1989 Wildlife Technician, Florida Game and Freshwater Fish Commission, Okeechobee, Florida
Education and Certifications
Ph.D. 2000 Oregon State University Wildlife Science
M.S. 1988 Texas A&M University Wildlife Ecology
B.S. 1985 Northland College Biology/Outdoor Education
Affiliations and Memberships*
Affiliate Faculty - University of Alaska Fairbanks, College of Fisheries and Ocean Sciences
Adjunct Professor - Simon Fraser University
The Wildlife Society
Pacific Seabird Group
Sea Duck Joint Venture Continental Technical Team
Science and Products
Winter philopatry of harlequin ducks in Prince William Sound, Alaska
Patterns and processes of population change in selected nearshore vertebrate predators
Long-term ecosystem repsonse to the Exxon Valdez oil spill
Harlequin duck (Histrionicus histrionicus) perspective: Harlequin duck population recovery following the Exxon Valdez oil spill: Progress, process, and constraints
Harlequin duck population recovery following the 'Exxon Valdez' oil spill: Progress, process and constraints
Intraspecific variation in nutrient reserve use during clutch formation by Lesser Scaup
Winter survival of adult female harlequin ducks in relation to history of contamination by the Exxon Valdez oil spill
Testing assumptions for unbiased estimation of survival of radiomarked harlequin ducks
Correlates of Harlequin Duck densities during winter in Prince William Sound, Alaska
Densities of Barrow's goldeneyes during winter in Prince William Sound, Alaska in relation to habitat, food, and history of oil contamination
Cytochrome P450 1A induction in sea ducks inhabiting nearshore areas of Prince William Sound, Alaska
Applying metapopulation theory to conservation of migratory birds
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
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Winter philopatry of harlequin ducks in Prince William Sound, Alaska
We used capture-mark-recapture data to assess winter philopatry by Harlequin Ducks (Histrionicus histrionicus) in Prince William Sound, Alaska, during winters 1995–1997 and 2000–2001. Philopatry was quantified using homing rates, which were estimated as the proportion of birds recaptured at their original site out of all recaptured birds. Between-year homing rates of 0.95 (95% CI: 0.87–1.00) and 1AuthorsSamuel A. Iverson, Daniel Esler, Daniel RizzoloPatterns and processes of population change in selected nearshore vertebrate predators
Sea otters and harlequin ducks have not fully recovered from the oil spill. This project will explore links between oil exposure and the lack of population recovery, with the intent of understanding constraints to recovery of these species and the nearshore environment. In FY 02, sea otter work will include aerial surveys of distribution and abundance and estimates of age-specific survival rates.AuthorsJames L. Bodkin, Brenda E. Ballachey, T.A. Dean, Daniel EslerLong-term ecosystem repsonse to the Exxon Valdez oil spill
The ecosystem response to the 1989 spill of oil from the Exxon Valdez into Prince William Sound, Alaska, shows that current practices for assessing ecological risks of oil in the oceans and, by extension, other toxic sources should be changed. Previously, it was assumed that impacts to populations derive almost exclusively from acute mortality. However, in the Alaskan coastal ecosystem, unexpectedAuthorsC. H. Peterson, S.D. Rice, J.W. Short, Daniel Esler, James L. Bodkin, Brenda E. Ballachey, D.B. IronsHarlequin duck (Histrionicus histrionicus) perspective: Harlequin duck population recovery following the Exxon Valdez oil spill: Progress, process, and constraints
Following the 1989 Exxon Valdez oil spill in Prince William Sound, Alaska, we studied the status of recovery of harlequin duck (Histrionicus histrionicus) populations during 1995-1998. We evaluated potential constraints to full recovery, including (1) exposure to residual oil, (2) food limitation, and (3) intrinsic demographic limitations on population growth rates. In this paper, we synthesize thAuthorsDaniel Esler, Timothy D. Bowman, Kimberly A. Trust, Brenda E. Ballachey, Thomas A. Dean, Stephen C. Jewett, Charles E. O'ClairHarlequin duck population recovery following the 'Exxon Valdez' oil spill: Progress, process and constraints
Following the 1989 'Exxon Valdez' oil spill in Prince William Sound, Alaska, we studied the status of recovery of harlequin duck Histrionicus histrionicus populations during 1995 to 1998. We evaluated potential constraints on full recovery, including (1) exposure to residual oil; (2) food limitation; and (3) intrinsic demographic limitations on population growth rates. In this paper, we synthesizeAuthorsDaniel Esler, Timothy D. Bowman, Kimberly A. Trust, Brenda E. Ballachey, Thomas A. Dean, Stephen C. Jewett, Charles E. O'ClairIntraspecific variation in nutrient reserve use during clutch formation by Lesser Scaup
We studied nutrient reserve dynamics of female Lesser Scaup (Aythya affinis) to identify sources of intraspecific variation in strategies of nutrient acquisition for meeting the high nutritional and energetic costs of egg formation. We collected data from interior Alaska and combined these with data for Lesser Scaup from midcontinent breeding areas (Afton and Ankney 1991), allowing a rangewide anaAuthorsDaniel Esler, J. Barry Grand, Alan D. AftonWinter survival of adult female harlequin ducks in relation to history of contamination by the Exxon Valdez oil spill
Harlequin duck (Histrionicus histrionicus) life-history characteristics make their populations particularly vulnerable to perturbations during nonbreeding periods. The 1989 Exxon Valdez oil spill was a major perturbation to nonbreeding habitats of harlequin ducks in Prince William Sound, Alaska, which resulted in population injury. To assess the status of population recovery from the oil spill andAuthorsDaniel Esler, Joel A. Schmutz, R. L. Jarvis, D.M. MulcahyTesting assumptions for unbiased estimation of survival of radiomarked harlequin ducks
Unbiased estimates of survival based on individuals outfitted with radiotransmitters require meeting the assumptions that radios do not affect survival, and animals for which the radio signal is lost have the same survival probability as those for which fate is known. In most survival studies, researchers have made these assumptions without testing their validity. We tested these assumptions by coAuthorsDaniel Esler, Daniel M. Mulcahy, Robert L. JarvisCorrelates of Harlequin Duck densities during winter in Prince William Sound, Alaska
We evaluated relationships of Harlequin Duck (Histrionicus histrionicus) densities to habitat attributes, history of habitat contamination by the 1989 Exxon Valdez oil spill, and prey biomass density and abundance during winters 1995-1997 in Prince William Sound, Alaska. Habitat features that explained variation in duck densities included distance to streams and reefs, degree of exposure to wind aAuthorsDaniel Esler, Timothy D. Bowman, T.A. Dean, Charles E. O'Clair, S.C. Jewett, L.L. McDonaldDensities of Barrow's goldeneyes during winter in Prince William Sound, Alaska in relation to habitat, food, and history of oil contamination
We evaluated variation in densities of Barrow's Goldeneyes (Bucephala islandica) during winter at 214 sites within oiled and unoiled study areas in Prince William Sound, Alaska in relation to physical habitat attributes, prey biomass, and history of habitat contamination by the 1989 Exxon Valdez oil spill. Using general linear model analyses, we found that goldeneye densities were positively assocAuthorsDaniel Esler, Timothy D. Bowman, Charles E. O'Clair, Thomas A. Dean, Lyman L. McDonaldCytochrome P450 1A induction in sea ducks inhabiting nearshore areas of Prince William Sound, Alaska
Following the Exxon-Valdez oil spill, hepatic rates of EROD activity and thus, P450 1A expression, were significantly higher in harlequin ducks (Histrionicus histrionicus) and Barrow’s goldeneyes (Bucephala islandica) from oiled areas of Prince William Sound, Alaska when compared to birds from unoiled sites. Polychlorinated biphenyl exposure did not account for areal differences in P450 1A inductiAuthorsKimberly A. Trust, Daniel Esler, Bruce R. Woodin, John J. StegemanApplying metapopulation theory to conservation of migratory birds
Metapopulation theory has proven useful for understanding the population structure and dynamics of many species of conservation concern. The metapopulation concept has been applied almost exclusively to nonmigratory species, however, for which subpopulation demographic independence—a requirement for a classically defined metapopulation - is explicitly related to geographic distribution and dispersAuthorsDaniel EslerNon-USGS Publications**
Agüero, M. L., P. G. Borboroglu, and D. Esler. 2014. Trophic ecology of breeding white-headed steamerduck (Tachyeres leucocephalus). Waterbirds 37:88-93.Hogan, D., D. Esler, and J. E. Thompson. 2013. Duration and Phenology of Remigial Molt of Barrow's Goldeneye. Condor 115 (4):762-768Palm, E. C., D. Esler, E. M. Anderson, T. D. Williams, and M. T. Wilson. 2013. Variation in physiology and energy management of wintering white-winged scoters in relation to local habitat conditions. Condor 115 (4) :750-761.Hogan, D., D. Esler, and J. E. Thompson. 2013. Variation in body mass and foraging effort of Barrow’s goldeneyes (Bucephala islandica) during remigial molt. Auk 130 (2):313-322.Palm, E. C., D. Esler, E. M. Anderson, T. D. Williams, O. P. Love, and M. T. Wilson. 2013. Baseline corticosterone in wintering marine birds: methodological considerations and ecological patterns. Physiological and Biochemical. Zoology 86 (3):346-353.Hogan, D., J. E. Thompson, and D. Esler. 2013. Survival of Barrow’s goldeneyes during remigial molt and fall staging. Journal of Wildlife Management 77:701-706.Heath, J. P., W. A. Montevecchi, and D. Esler. 2012. A method for quantifying consistency in animal distributions using survey data. PLoS One 7(9): e44353.Palm, E. C., D. Esler, E. M. Anderson, and M. T. Wilson. 2012. Geographic and temporal variation in diet of wintering white-winged scoters. Waterbirds 35 (4):577-589.Federer, R., T. Hollmén, D. Esler, and M. J. Wooller. 2012. Stable carbon and nitrogen isotope discrimination factors for quantifying spectacled eider nutrient allocation to egg production. Condor 114:726-732.Agüero, M. L., P. G. Borboroglu, and D. Esler. 2012. Distribution and abundance of Chubut steamerducks: an endemic species to central Patagonia, Argentina. Bird Conservation International 22:307-315.Hogan, D., J. E. Thompson, D. Esler, and W. S. Boyd. 2011. Discovery of important postbreeding sites for Barrow’s goldeneye in the boreal transition zone of Alberta. Waterbirds 34(3):261-268.Takekawa, J. Y., S. W. De La Cruz, M. T. Wilson, E. C. Palm, J. Yee, D. R. Nyeswander, J. R. Evenson, J. M. Eadie, D. Esler, W. S. Boyd, and D. H. Ward. 2011. Breeding distribution and ecology of Pacific coast surf scoters. Pages 41-64 in J.V. Wells, editor. Boreal Birds of North America: a hemispheric view of their conservation links and significance. Studies in Avian Biology (Number 41). University of California Press, Berkeley.Agüero, M. L., P. G. Borboroglu, and D. Esler. 2010. Breeding habitat attributes and nest site selection of Chubut steamerducks in Patagonia, Argentina. Emu 110:302-306.Federer, R., T. Hollmén, D. Esler, M. J. Wooller, and S. W. Wang. 2010. Stable carbon and nitrogen isotope discrimination factors from diet to blood plasma, cellular blood, feathers, and adipose fatty acids in spectacled eiders (Somateria fischeri). Canadian Journal of Zoology 88(9): 866-874.Esler, D., and J. C. Bond. 2010. Cross-seasonal dynamics in body mass of male harlequin ducks: a strategy for meeting costs of reproduction. Canadian Journal of Zoology 88:224-230.Iverson, S. A., and D. Esler. 2010. Harlequin duck population dynamics following the 1989 Exxon Valdez oil spill: assessing injury and projecting a timeline to recovery. Ecological Applications 20:1993-2006.Esler, D., and S. A. Iverson. 2010. Female harlequin duck winter survival 11 to 14 years after the Exxon Valdez oil spill. Journal of Wildlife Management 74(3):471-478.Anderson, E. M., J. R. Lovvorn, D. Esler, W. S. Boyd, and K. C. Stick. 2009. Using predator distributions, diet, and condition to evaluate seasonal foraging sites: sea ducks and herring spawn. Marine Ecology Progress Series 386:287-302.Bond, J. C., S. A. Iverson, N. B. MacCallum, C. M. Smith, H. J. Bruner, and D. Esler. 2009. Variation in breeding season survival of female harlequin ducks. Journal of Wildlife Management 73: 965-972.De La Cruz, S. W., J. Y. Takekawa, M. T. Wilson, D. R. Nysewander, J. R. Evenson, D. Esler, W. S. Boyd, and D. H. Ward. 2009. Surf Scoter (Melanitta perspicillata) spring migration routes and chronology: A synthesis of Pacific coast studies. Canadian Journal of Zoology 87:1069-1086.LeBourdais, S. V., R. C. Ydenberg, and D. Esler. 2009. Fish and harlequin ducks compete on breeding streams. Canadian Journal of Zoology 87(1): 31-40.Gorman, K. B., D. Esler, R. L. Walzem, and T. D. Williams. 2009. Plasma yolk precursor dynamics during egg production by female greater scaup (Aythya marila): characterization and indices of reproductive state. Physiological and Biochemical Zoology 82(4): 372-381.Žydelis, R., D. Esler, M. Kirk, and W. S. Boyd. 2009. Effects of off-bottom shellfish aquaculture on winter habitat use by molluscivorous sea ducks. Aquatic Conservation: Marine and Freshwater Ecosystems 19:34-42.Bond, J. C., D. Esler, and T. D. Williams. 2008. Breeding propensity of female harlequin ducks. Journal of Wildlife Management 72(6):1388-1393.Lok, E. K., M. Kirk, D. Esler, and W. S. Boyd. 2008. Movements of pre-migratory surf and white-winged scoters in response to Pacific herring spawn. Waterbirds 31:385-393.Bond, J.C., and D. Esler. 2008. Bill entanglement in subcutaneously-anchored radio transmitters on harlequin ducks. Wilson Journal of Ornithology 120(3): 599-602.Gorman, K. B., D. Esler, P. L. Flint, and T. D. Williams. 2008. Nutrient reserve dynamics during egg production by female greater scaup (Aythya marila): relationships with timing of reproduction. Auk 125:384-394.Lewis, T. L., D. Esler, and W. S. Boyd. 2008. Foraging behaviors of surf and white-winged scoters in relation to clam density: inferring food availability and habitat quality. Auk 125:149-157.Kirk, M., D. Esler, and W. S. Boyd. 2007. Foraging effort of surf scoters (Melanitta perspicillata) wintering in a spatially and temporally variable prey landscape. Canadian Journal of Zoology 85(12): 1207-1215.Kirk, M., D. Esler, and W. S. Boyd. 2007. Morphology and density of mussels on natural and aquaculture structure habitats: implications for sea duck predators. Marine Ecology Progress Series 346:179-187.Bond, J. C., D. Esler, and K. A. Hobson. 2007. Isotopic evidence for sources of nutrients allocated to clutch formation by harlequin ducks. Condor 109:698-704.Iverson, S. A., and D. Esler. 2007. Survival of female harlequin ducks during wing molt. Journal of Wildlife Management 71:1220-1224.Bond, J. C., and D. Esler. 2006. Nutrient acquisition by female harlequin ducks prior to migration and reproduction: evidence for body mass optimization. Canadian Journal of Zoology 84: 1223-1229.Žydelis, R., D. Esler, W. S. Boyd, D. Lacroix, and M. Kirk. 2006. Habitat use by wintering surf and white-winged scoters: effects of environmental attributes and shellfish aquaculture. Journal of Wildlife Management 70(6):1754-1762.Iverson, S. A., and D. Esler. 2006. Site fidelity and the demographic implications of winter movements by a migratory bird, the harlequin duck. Journal of Avian Biology 37:219-228.Lewis, T. L., D. Esler, W. S. Boyd, and R. Žydelis. 2005. Nocturnal foraging behavior of wintering surf scoters and white-winged scoters. Condor 107:636-646.Lacroix, D. L., W. S. Boyd, D. Esler, M. Kirk, T. L. Lewis, and S. Lipovsky. 2005. Surf scoters aggregate in association with ephemerally abundant polychaetes. Marine Ornithology 33:61-63.Žydelis, R., and D. Esler. 2005. Response of wintering Steller’s eiders to herring spawn. Waterbirds 28:344-350.Iverson, S. A., D. Esler, and W. S. Boyd. 2003. Plumage characteristics as an indicator of age class in the surf scoter. Waterbirds 26:56-61.Weller, M. W., K. C. Jensen, E. J. Taylor, M. Miller, K. S. Bollinger, D. V. Derksen, D. Esler, and C. Markon. 1994. Assessment of shoreline vegetation in relation to use by molting black brant on the Alaska coastal plain. Biological Conservation 70:219 225.Esler, D. 1992. Habitat use by piscivorous birds on a power plant cooling reservoir. Journal of Field Ornithology 63:241 249.Esler, D. 1990. Avian community responses to hydrilla invasion. Wilson Bulletin 102:427 440.Esler, D. 1990. Waterfowl habitat use on a Texas reservoir with hydrilla. Proceedings of the Annual Conference of the Southeastern Association of Fish and Wildlife Agencies. 44:390 400.Esler, D. 1989. An assessment of American coot herbivory of hydrilla. Journal of Wildlife Management 53:1147 1149.**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
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*Disclaimer: Listing outside positions with professional scientific organizations on this Staff Profile are for informational purposes only and do not constitute an endorsement of those professional scientific organizations or their activities by the USGS, Department of the Interior, or U.S. Government