docAvian habitat and nesting use in the northeast region of the National
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Avian habitat and nesting use in the northeast region of the National
__________________ Avian habitat and nesting use in the northeast region of the National Petroleum Reserve – Alaska Ikpikpuk River site -2010 report A report prepared by Joe Liebezeit and Steve Zack of the Wildlife Conservation Society for The Bureau of Land Management, Alaska Department of Fish and Game, North Slope Borough, U.S. Fish and Wildlife Service & other interested parties / stakeholders This document is submitted as an interim report in fulfillment of BLM grant L10AS00057 December 2010 TABLE OF CONTENTS TABLE OF CONTENTS............................................................................................................ ii LIST OF FIGURES ................................................................................................................... iii LIST OF TABLES..................................................................................................................... iv Executive Summary.................................................................................................................... 1 INTRODUCTION & BACKGROUND..................................................................................... 2 OBJECTIVES ............................................................................................................................. 2 STUDY AREA ........................................................................................................................... 3 METHODS ................................................................................................................................. 3 Study area delineation, plot establishment and setup ................................................................. 3 Species richness and abundance, nest discovery, nest monitoring, and fate assessment ........... 4 Nest predator identification ........................................................................................................ 5 Potential predator abundance and microtine activity.................................................................. 6 Habitat use, vegetative concealment, snow cover, and weather assessment .............................. 6 Data analysis ............................................................................................................................... 6 RESULTS ................................................................................................................................... 8 Relative abundance and diversity of avifauna ............................................................................ 8 Nest density, nest age, nesting success, and nest initiation ........................................................ 8 Nest predator identification ........................................................................................................ 9 Nest predator abundance........................................................................................................... 10 Microtine activity and abundance............................................................................................. 10 Habitat use, vegetative concealment, snow cover, and weather assessment ............................ 10 DISCUSSION........................................................................................................................... 11 ACKNOWLEDGEMENTS...................................................................................................... 13 LITERATURE CITED ............................................................................................................. 13 ii LIST OF FIGURES Figure 1. The Ikpikpuk River study site and study plot locations, National Petroleum Reserve, Alaska, 2010. “ASDN” = Arctic Shorebird Demographics Network.................................. 18 Figure 2. Pictures from the Ikpikpuk River study site, National Petroleum Reserve - Alaska. .. 19 Figure 3. Daily survival rates (± 1 SE) for the three most common nesting species at the Ikpikpuk River and Prudhoe Bay Oilfield study sites in 2010, Arctic coastal plain, Alaska. ............................................................................................................................................... 20 Figure 4. Mean nest initiation date (± 1 SE) for the three most common nesting birds at the Ikpikpuk River and Prudhoe Bay Oilfield study sites in 2010, Arctic coastal plain, Alaska. ............................................................................................................................................... 20 Figure 5. Photographic display of the remote camera system used to monitor tundra-nesting birds for predation events and two images of recorded predation events, Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010........................................................ 21 Figure 6. Location of camera-monitored nests and identified predators at subset of nests. ........ 22 Figure 7. Average number of potential nest predators (± 1 SE) detected in or near study plots / 30 min survey period at the Ikpikpuk River and Prudhoe Bay Oilfield study sites, Alaska Coastal Plain, Alaska, 2010. “Other predators” include Red Fox at both sites and Arctic ground squirrels at Ikpikpuk only. ........................................................................................ 23 Figure 8. Number of nests found in each landform type within study plots at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Unit 0 = non-patterned ground; Unit 2 = high-centered polygons (≤ 0.5m center-trough relief); Unit 3 = Low-centered polygon (rim-center relief ≤0.5m); Unit 4 = Low-centered polygon (rim-center relief >0.5m); Unit 5 = Mixed high and low centered polygons; Unit 7 = Strangmoor and/or disjunct polygon rims; Unit 8 = Hummocky terrain; Unit 9 = Reticulate-patterned ground; Unit A: Alluvial Floodplain. ............................................................................................................................ 23 Figure 9. Number of nests found in each ecotype class (local-scale ecosystems) as defined by Jorgensen and Heiner (2003). ............................................................................................... 24 Figure 10. Mean snow cover (%) for survey dates on all plot location fitted with linear trend, Ikpikpuk River study site, National Petroleum Reserve – Alaska, 2010.............................. 24 Figure 11. Mean daily temperatures (°°C ± 1 SE) during the core breeding season (10 June to 13 July) at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, and the Prudhoe Bay oilfield study site, 2010. .................................................................................. 25 iii LIST OF TABLES Table 1. Bird diversity and relative abundance at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010........................................................................................ 26 Table 2. Number of discovered nests and nest density for each species from the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010........................................................ 27 Table 3. Summary of daily survival rate (DSR) and Mayfield nesting success estimates of tundra-breeding birds at the Ikpikpuk River study site, National Petroleum Reserve Alaska, 2010. ........................................................................................................................ 28 Table 4. Nest initiation dates of tundra-nesting birds at the Ikpikpuk River study site, National Petroleum Reserve, Alaska, 2010. ........................................................................................ 29 Table 5. Summary of camera-monitored nest information at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. ........................................................................ 30 Table 6. Date and time of predation events, Ikpikpuk River study site, National Petroleum Reserve, Alaska, 2010........................................................................................................... 31 Table 7. Average number of all potential predators (and noted absences of other key predators) recorded during predator surveys for four time periods on and near study plots at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. ............................. 32 Table 8. Summary of overhead nest concealment for the most common species (n ≥ 10) and species groups at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. ............................................................................................................................................... 33 iv Executive Summary In this report we summarize preliminary results from our first year of nesting bird research at the Ikpikpuk River study site in the NE National Petroleum Reserve – Alaska (NPR-A). The overall goal of this effort is to provide land managers and other stakeholders (including the BLM, NSB, ADFG, and others) novel information on breeding birds (and other parameters that may influence their populations) so that effective management decisions can be made and implemented to conserve nesting bird populations in the region. In this report we assess key parameters at the Ikpikpuk site including: breeding species abundance and diversity, nest density, nest survivorship, nest initiation dates, identity and relative abundance of potential nest predators, and assess other variables that may influence breeding birds including habitat use, snow cover, weather conditions, and lemming abundance. We also compare these findings to those at a site in the Prudhoe Bay oilfields where comparable data were collected in 2010. We discovered and monitored 184 nests of 18 species from 9 June to 10 July, 2010. Semipalmated Sandpipers, Lapland Longspurs, and Pectoral Sandpiper nests accounted for the majority (58%) of those found. Species diversity of nesting birds was higher at Ikpikpuk compared to Prudhoe Bay (H' = 2.20 vs.1.92, respectively). Overall nest density was also higher at Ikpikpuk compared to Prudhoe Bay (125.8 vs. 93.3 nests / km2). Among all species, 100 nests successfully hatched / fledged, 59 failed, and 25 nests were of unknown or undetermined fate. Nest predation was the most important cause of nest failure (92%). Other sources of nest failure included abandonment, infertile eggs and trampling likely due to caribou. Passerines (mostly Lapland Longspurs) had significantly lower survivorship compared to shorebirds. Nest survivorship was lower at Prudhoe Bay for two of the three most common species compared to Ikpikpuk, however these differences were not significant. We used 15 Reconyx camera systems to monitor 35 nests of six species for nest predators. Fifteen nests successfully hatched / fledged, 13 were predated, six were of unknown fate, and one nest was still active at the end of the season when the camera was removed. Of the 13 predation events at camera-monitored nests, we identified arctic ground squirrels as the predator (or likely predator) in nine cases while arctic fox were identified as predators in two cases. Two predation events were not recorded because the cameras did not trigger. These results suggest that arctic ground squirrels are the most important predator at the site. This result contrasts with the predator surveys which identified Glaucous Gulls and Parasitic Jaegers as the most prevalent potential nest predators. We also observed Long-tailed Jaegers, arctic ground squirrel, and red fox on the predator surveys. At Prudhoe Bay, Glaucous Gulls and Parasitic Jaegers were also the most prevalent potential nest predators based on surveys; however the camera evidence indicated that arctic fox were the most important predator. In 2010, lemming abundance was low at Ikpikpuk, similar to Prudhoe Bay. Correspondingly, Pomarine Jaegers, a lemming obligate species, were not observed nesting this year at the site and were rarely seen after mid-June. Most birds nested in the “lowland wet meadow” ecotype, which at this site, is comprised largely of low-center polygon landform type. Lapland Longspurs had higher vegetative concealment over nests than shorebird species and successful longspur nests had significantly more concealment than predated nests. Although overall temperatures at Ikpikpuk seemed particularly cool in June (compared to previous years at other sites), a warm spike in temperature in early June likely explains the early snow melt witnessed this year. Snow melt at Ikpikpuk lagged behind Prudhoe Bay and we correspondingly observed significantly later nest initiation dates at Ikpikpuk. 1 INTRODUCTION & BACKGROUND The Arctic Coastal Plain (ACP) of Alaska, encompassing a vast region (98,200 km2), supports internationally important populations of breeding birds during the brief Arctic summer season. Over 50 species of birds, representing millions of individuals, nest in this region (Johnson and Herter 1989) including significant populations of shorebirds (Pitelka 1974, Johnson et al. 2007). In addition, important populations of waterfowl and water birds breed and stage here (King and Hodges 1979, Earnst et al. 2005). Yet, many of the bird populations that depend so heavily on their arctic breeding and staging grounds are currently experiencing population declines including shorebird species (Brown et al. 2001, Morrison et al. 2006) such as the Buff-breasted Sandpiper (Tryngites subruficollis) and waterfowl including the Spectacled (Somateria fischeri) and Steller’s Eider (Polysticta stelleri; Stehn et al. 1993, Kertell 1991). Within the ACP, the National Petroleum Reserve (NPR-A), at 9.5 million hectares, is the largest piece of public land in the United States and contains a significant portion of Alaska’s ACP. Because of the disproportionately high density of lakes, ponds, and wet meadows in the coastal plain region of the NPR-A, this rich habitat includes important nesting and staging grounds for migratory bird species. This landscape contains a mosaic of wet and dry tundra habitats, with different bird species tied to each. The NPR-A is also a region of oil development interest and its eastern boundary lies adjacent to the current oil field infrastructure of Prudhoe Bay, Kuparuk, and Alpine. Human activities related to energy development on the ACP may negatively impact nesting birds by direct loss of habitat through infrastructure expansion, habitat degradation via road dust and hydrology alteration, vehicle traffic / noise, and pollution (Troy 2000; NAS 2003). Furthermore, increasing human-subsidized nest predator populations’ can subject nesting birds to increasing predation pressure (Day 1998, NAS 2003, Liebezeit et al. 2009). On the ACP, known subsidized nest predators (species that prey on eggs and chicks at active bird nests) include arctic fox (Alopex lagopus), Glaucous Gull (Larus hyperboreus), and the Common Raven (Corvus corax). The reported increases in nest predators is thought to be due to the availability of human food subsidies via landfills, dumpsters, and other sources, and also due to the availability of artificial den and nest sites, including culverts, towers, and other human structures both in oil fields and in the villages (Day 1998, NAS 2003). In a recent study, nests of some bird species were found to have significantly lower nest survivorship within 5 km of oil infrastructure (Liebezeit et al. 2009). Although biologists have monitored bird populations on the coastal plain of the NPR-A for years via aerial surveys (e.g. Larned et al. 2005), information on smaller bird species (such as shorebirds) is difficult to collect from the air and is therefore underrepresented in previous studies. Because of the recognized importance of the NPR-A as a breeding ground for nesting birds, it is critical that land managers have good baseline data to help inform land-use decisions as oil development will likely expand into this region. Among the most important pieces of information needed include determining how successful nesting birds are at reproducing young (nest survivorship), what habitats different species select for nesting, what are the abundances and identity of nest predators, and how do these parameters compare to nearby anthropogenically altered areas. In this way, stakeholders in the region will be able to make the most informed decisions to conserve nesting bird populations in the NE NPR-A. OBJECTIVES The overall objective is to determine the habitat use and nesting patterns of tundra nesting birds at two sites in the NE NPR-A (Ikpikpuk and Teshekpuk), and compare / contrast those patterns 2 with similar data obtained from the oilfields (Prudhoe Bay and Kuparuk). A secondary goal is to assess predator abundance and identity between the remote Ikpikpuk site and the human-altered Prudhoe Bay site. The combined data set will provide new information to aid effective wildlife management by the administrators of the NPR-A (Bureau of Land Management), and other key stakeholders (e.g. North Slope Borough) in the region. This project also allows us to contribute toward other collaborative studies (e.g. Arctic Shorebird Demography Network). For this annual report, we summarize the finding from the first year of the study at the Ikpikpuk study site and make comparisons to 2010 findings at the Prudhoe Bay oilfield study site. Specifically, we: 1) Summarize nesting biology parameters including breeding species abundance and diversity, nest density, nest survivorship, and nest initiation dates. 2) Determine the identity of nest predators at Ikpikpuk using remote camera systems and assess relative abundance of potential nest predators. 3) Assess other variables that may influence nesting birds including habitat use, snow cover, weather conditions, and microtine abundance. STUDY AREA The WCS study site on the Ikpikpuk River is roughly 30 km SSE of the Ikpikpuk River Delta on the east side of the river (center of the study area is at 70.55343° N, 154.69750° W). The study area is bordered to the west, east, and north by forks of the Ikpikpuk River. To the south, the study area is bounded 4 km from our field camp (Figs. 1 & 2). The total area of the study area is approximately 27 km2. The study site is within the Arctic Coastal Plain zone of the North Slope which is characterized by a mosaic of tundra with a gradient of dry, upland tundra, often with high densities of cotton grass tussocks, to wet and emergent vegetation in the lower areas. The tundra wetland complex is dominated by numerous ponds and lakes created by the thaw-lake cycle (Walker et al. 1980). Microrelief is characterized by the presence of high and low polygons, hummocks, tussocks, and strangmoor / disjuct polygon ridges. METHODS Study area delineation, plot establishment and setup The site and the camp location were selected non-randomly during a reconnoitering visit in June 2009. The criteria we used to select the site included 1) access to an adequate landing area for a fixed-wing plane equipped with tundra tires, 2) availability of a fresh water source for camp use, and 3) easy access to suitable nesting habitat for field research. The size of this area was chosen based on the logistics of our daily work load and maximum distance we could realistically cover on foot to our study plots. Plot locations were selected by randomly choosing a point within a grid of points spaced 300 m apart in all cardinal directions across the defined study area. The first point chosen (omitting points in water bodies and the adjacent flood plains1 around some lakes) was used as the first plot location. Subsequent plots were placed systematically in relation to the first plot location. The plots are spatially clustered in groups of four for safety and logistic reasons. All told, we established 12 10-ha plots (Fig. 1). To determine plot orientation, we first selected a random compass bearing. If the randomly selected orientation resulted in open water covering greater than 20% of the plot area, we selected another random orientation until a more appropriate region was selected. 1 Floodplain areas of some lakes were flooded the first few weeks of the field season 3 ArcGIS 9.3 GIS software was used to aid plot site delineation. We followed plot design methodology developed by Troy (1996) establishing 10 ha (100 m x 1000 m) plots. Plots were marked at 50 m intervals along centerline axes using 1.2 m wooden survey stakes; thereby subdividing the 10 ha plots into 40 50-m x 50-m units. For recording nest locations and landform type, each unit was further subdivided into four 25-m x 25-m quadrats. Species richness and abundance, nest discovery, nest monitoring, and fate assessment We estimated relative species richness and abundance based on casual, non-systematic observations of all species during our day-to-day activities at work in the field and at rest at our base camp. We searched for nests from 12 June to 30 June 2010 from approximately 0900 to 2000 Alaska Daylight Time (AKDT). We used two techniques to discover nests: rope-dragging and single-person nest searches. The rope-drag technique consists of two observers stretching a 50 m rope from the plot center to the outer edge and slowly walking while dragging the rope on the ground, covering the entire plot. When a bird flushes, observers stop long enough to find and mark the nest. The single-person nest searches are conducted by one observer per plot walking “W” transects within each plot grid during which attendance to bird behavior leads observers to nest locations (Troy 1996). To be consistent with our field efforts at other sites, plots were searched systematically by alternating two rope-drag sessions with two single-person nest searches (order: rope-drag, single-person, rope-drag, single-person) following a systematic schedule as defined in the standardized field protocol (Liebezeit 2010). Several nests (n = 21) were found incidentally (outside of the designated nest search periods while conducting other field duties) between 9 June and 10 July 2010. All nests were marked with a plain wooden tongue depressor on which was written the species, nest identification number and coordinates to the nest. The tongue depressor was placed approximately 1 m from the nest in the direction of the study plot centerline. A second fluorescent orange tongue depressor (with the same information as the plain marker) was placed at the plot centerline to further assist in relocating the nest. At each nest, information including species, location of nest, nest identification number, observer, date, time, and method of discovery were recorded onto a data form. We conducted nest monitor visits systematically every 3-6 d until fates were determined. Nest monitoring began on 15 June during the first round of rope-drag searches and continued in tandem with nest searches or independently when necessary. After nest searches ended, we continued to monitor nests until the end of the field season on 13 July. We estimated nest fate based on criteria used by other researchers (Troy 1993, Mabee 1997, Martin et al.1997). A “hatched” nest refers to one that is believed to have successfully hatched at least one offspring of a nester with precocial young (i.e. shorebirds and waterfowl). A “fledged” nest refers to one in which at least one nestling was successfully able to leave the nest. This only applies to the Lapland Longspur (Calcarius lapponicus) and Savannah Sparrows (Passerculus sandwichensis) since they were the only nesters that produced altricial young at this site. We assumed a nest hatched / fledged successfully if at least two of the following conditions were met: the nest was empty within 4 d of the expected hatch date (2 d for passerines), chicks were observed in the nest or nearby (within 10 m), egg pip holes were observed on the penultimate visit, and / or other evidence including presence of egg pip fragments (~1-4 mm), and membranes easily peel away from egg pieces (waterfowl). We assumed predation if the nest contents were gone at least 4 d prior to the expected hatch / fledge date and / or other evidence left at the nest indicated predation including large egg-shell pieces with yolk or blood present, destroyed nest cup, and evidence of previous partial predation. Other potential causes of nest failure include inclement weather, abandonment due to infertile eggs, trampling by caribou 4 (Rangifer tarandus), and human-induced causes. Nest fate was classified as “unknown” if we did not have clear evidence or had contradictory evidence as to nest fate. Nests that were still active when we left the field were classified as “undetermined” fate. We estimated nest age using one or more of the following methods (1) discovery of an incomplete clutch during the laying stage and forward-calculating, (2) back-calculating from hatch day, (3) nestling development (passerines only), or (4) employing the egg flotation technique (Liebezeit et al. 2007). For extrapolating age of the nest for methods (1) and (2) we used incubation and nestling stage lengths based on published literature (Poole et al. 2003) and assumed birds laid one egg per day. We defined nest age as beginning on the day the first egg was laid until the date the nest was no longer active. We determined the nestling age of passerines by taking detailed notes on nestling development at nests of known age and using this information to estimate age at nests found during the nestling stage. We also used information in the literature on Lapland Longspur development to assist in aging longspur nestlings (Hussell and Montgomerie 2002). In order to minimize anthropogenic effects on predation rate we conducted nest checks from a distance using binoculars (if possible), avoided creating dead-end paths when checking nests, did not approach an active nest if predators were in the vicinity, did not eat or set equipment down near active nests, and covered unattended waterfowl nests with vegetation or down. After nests were no longer active, we determined if they were within the plot using a tape measure, and we used a Garmin Legend Global Positioning System (GPS) receiver to obtain geographic coordinates of the nest location (error ± 6 m). We set the GPS units to map datum WGS 84 and decimal minutes for recording nest locations. Nest predator identification From 12 June to 13 July we monitored active shorebird and passerine nests for nest predators using 15 PC-90 Reconyx motion-triggered camera systems (www.reconyx.com). The camera systems were mounted on 1.2 m-long 1 cm-wide aluminum dowels secured into the ground or held directly on the tundra secured with rebar stakes and 18-gauge wire. Cameras were placed within 5 m of the nest with the infrared beam aligned about 0.15 m above the nest. We attempted to place cameras >5 m from nests to minimize the likelihood that a given nest predator would associate camera presence but the units missed some predation events so (with advice from Reconyx) we decided to place cameras closer to the nests. We set the camera motion-trigger at a sensitivity setting of “high”. We also enabled the “rapid-fire mode, so five pictures would be taken upon any event that triggered the motion sensor. All pictures were recorded on 4-GB compact flash cards. The systems were checked every 3-4 d and flash cards and batteries were changed when necessary. These camera systems are easily transportable, weighing <2.5 kg each and five units fit easily in a medium-sized backpack. At this site, we set the camera system only on active shorebird and longspur nests that were in the incubation stage (or nestling stage for longspurs). Cameras were set up on or near the ASDN2 plots (Fig. 1). Cameras were moved from inactive nests to new nests as soon as possible. If there was a predation event, we avoided setting up the camera on another nest in the same area to avoid conditioning potential nest predators to its presence. Within these parameters, we selected nests opportunistically for camera set-up. 2 ASDN = Arctic Shorebird Demographic Network study plots 5 Potential predator abundance and microtine activity We conducted three sessions of timed point count surveys on all plots from 17 June to 7 July, between 0930 and 1800 AKDT. A point count session on each plot consisted of recording all visual and aural detections of potential predators up to 300 m from the observer during three 10 min surveys from fixed locations (centerline markers) within each study plot (for similar methodology see Ralph et al. 1993). Each count was conducted at least 10 min and 200 m from the previous one. We estimated predator distance from the observer (upon the initial sighting) by using rangefinders, by judging the distance using the plot marker stakes as reference points, or by pacing the distance on foot. We also noted general behavior and appearance of each predator to assist in distinguishing individuals from one another to avoid recounting. During each point count visit observers recorded date, time of arrival on plot, and time of plot departure. We monitored plots for microtine (lemming and vole) activity by tallying all individual microtines observed within each plot during predator survey visits. Brown lemmings (Lemmus sibiricus), collared lemmings (Dicrostonyx torquatus), northern red-backed voles (Myodes rutilus), tundra voles (Microtus oeconomus), and singing vole (Microtus miurus) are known to occur on the Arctic coastal plain of Alaska. We did not attempt to identify individuals to species in most cases because identification can be difficult without close examination of animals in the hand (Whitaker 1996). We also indirectly assessed mictrotine activity by recording incidental sightings of Pomarine Jaegers (Stercorarius pomarinus) and Snowy Owls (Bubo scandiaca). These species are known to nest much more prevalently in years of high lemming abundance and thus can be an indirect measure of microtine abundance. Habitat use, vegetative concealment, snow cover, and weather assessment We assigned the dominant landform type within the designated quadrat (25-m x 25-m subdivision of plot) of each nest location following the designation of Walker et al. (1980). These landforms are large-scale, geophysical features that may contain a variety of vegetation types. For a thorough description of landform types and classification see Liebezeit (2010) – Appendix J. For nests located outside of the plot boundaries, we estimated landform type within a 12.5 m radius of a given nest. We determined the ecotype (local-scale ecosystem) each nest was located in by overlaying nest location data over a raster map of the “Ecosystems of northern Alaska” map (Jorgensen and Heiner 2003) using the Hawth’s tool intersect point function in ArcGIS 9.3. We estimated % overhead vegetative concealment of all shorebird and passerine nests on the day nest fate was determined using an ocular tube following methods described by James and Shugart (1970). From 9 to 29 June, we estimated the percentage of tundra covered by snow to the nearest 10% within each 50-m x 50-m grid of each plot. From 10 June to 13 July we downloaded hourly relative humidity, air temperature, and wind speed / direction data, from a HOBO weather station we established at the site (Fig. 2). Data analysis We estimated species nest diversity and evenness at the site using the Shannon-Weiner Index. For this estimate we only used data for nests found within study plots. We calculated nest density by estimating the number of nests within plot boundaries per unit area (km2). We estimated nest initiation day by back-calculating from nests of known age to the date the first egg was laid. For both density and nest initiation estimates we omitted “re-nests” from the analysis. A re-nest is a second nesting effort by a pair of birds that failed in a previous 6 nesting attempt. We assumed that a nest initiated shortly after another failed within approximately 100 m of one another indicated a re-nest (but see Naves et al. 2008). We also assumed re-nesting took place when nests were initiated >14 d after this season’s mean initiation date for the respective species. None of the species we monitored are believed to re-nest after a successful nesting attempt with the possible exception of longspurs (see Custer and Pitelka 1977). For both nest density and nest initiation dates we made statistical comparisons between sites within year (Ikpikpuk and Prudhoe Bay for 2010) using 2-sample T-tests. We employed appropriate data transformations and / or removed extreme outliers to meet test assumptions (or, in some cases, we used the equivalent non-parametric tests if the assumptions of normality or equal variances were not met). Nest density per plot was the sample unit and for nest initiation date, individual nests were the sample units. We estimated nesting success using the constant survivorship model in Program MARK (White and Burnham 1999) which provides estimates of daily survival rate (DSR) and corresponding standard error estimates (as in Johnson 1979). To calculate the number of days nests were active (exposure days), for successful nests, we used the period between the estimated or known initiation date and hatch date. For nests with uncertain fate we used the last observed active date as the final exposure day to minimize downward bias (Manolis et al. 2000). For failed nests, Program MARK incorporates probabilities of failure for each day between the last observed active date and first observed inactive date thus no final exposure day is estimated. Unlike standard Mayfield estimates, Program MARK does not assume fate day as the midpoint between the last observed active and first observed inactive date. After DSR was calculated, we used incubation (and nestling stage) durations reported in the literature (Poole et al. 2003, Ehrlich et al. 1988) to estimate Mayfield nesting success (Mayfield 1975) for each species3. For species with sample sizes greater than 10 (Lapland Longspur, Semipalmated Sandpiper [Calidris pusilla], Pectoral Sandpiper [Calidris melanotos], Greater White-fronted Goose [Anser albifrons], Red Phalarope [Phalaropus fulicarius]) and for species groups4 we compared DSR both within and between sites (Ikpikpuk and Prudhoe Bay) with a χ2 test using program CONTRAST (Sauer and Williams 1989). For all species, we assumed one egg was laid per day, and that incubation started the day the last egg in the clutch was laid. We defined the beginning of the nestling stage (for passerines) as the day the first young hatched. Because of the paucity of nests found in the laying stage for any species, we did not calculate nesting success estimates for this nesting stage. We estimated the activity of potential nest predators across the study site by averaging the number of predator species detections per 30-min time period per plot. We estimated activity within four time periods defined as “early” (6/20 and before), “middle” (6/21 to 7/5), “late” (7/6 and after) and “season” (all periods). We did not record Artic Tern (Sterna paradisaea) or Sabine’s Gull (Xema sabini) as potential nest predators. We used the square root transformation to attempt to normalize predator count data prior to statistical tests (Afifi and Clark 1998). We compared predator detection differences between sites (Ikpikpuk vs. Prudhoe Bay) for all predators and for individual species within year (2010) using 2-sample T-tests (or, in some cases, we used the equivalent non-parametric tests if the assumptions of normality or equal variances were not met). 3 Mayfield estimates can not be calculated across species groups because incubation lengths for individual species differ. 4 A major difference between longspur and shorebird nesting success estimates is that longspur estimates include both the incubation and nestling stage. However, the duration of these combined stages (22 d) is comparable to the incubation stage length for most shorebirds, thus we felt justified in making these comparisons. 7 We compared nest concealment between species and species groups with adequate sample sizes (n ≥ 10) using 2-sample T-tests. If the assumptions of normality or equal variances were not met, we used appropriate data transformations or non-parametric analyses (Afifi and Clark 1998, Zar 1999). We also compared the frequency of landform types and ecotypes types for all within plot nests and displayed the results as histograms. We used linear regression of % snow cover per date to estimate trajectory of snow melt until date of completion. We summarized weather conditions across the time period measured and calculated corresponding standard errors. Unless otherwise stated, analyses were conducted using Microsoft Access 2000, Microsoft Excel, or NCSS 2000 (Hintze 2000). Results are reported as a mean ± SE, and were significant if P < 0.05. RESULTS Relative abundance and diversity of avifauna From 9 June to 13 July we detected 51 species of birds within the boundaries of the study site (Table 1). Of these species, 27 were known breeders because we discovered their nests on our study plots (n = 18; Table 2) or off plot (n = 9; Glaucous Gull, Long-tailed Jaeger [Stercorarius longicaudus], Parasitic Jaeger [Stercorarius parasiticus], Pacific Loon [Gavia pacifica], Yellowbilled Loon [Gavia stellata], Brant [Branta bernicla], King Eider [Somateria spectabilis], Sabine’s gull, and redpoll spp [Carduelis spp]). We suspect four other species were nesting in the area based on behavioral cues or other evidence of nesting (Red-necked Grebe [Podiceps grisegena], Tundra Swan [Cygnus columbianus], Greater Scaup [Aythya marila], and Spectacled Eider. Thus, at least 31 species likely breed within the study area. Compared to Prudhoe Bay, Ikpikpuk nest species diversity was higher (Ikpikpuk: H' = 2.20; Prudhoe Bay: H' = 1.92) although species evenness was similar between sites (Ikpikpuk=0.76; Prudhoe Bay=0.80). Nesting shorebird species diversity and evenness were very similar between sites (Ikpikpuk: H' = 1.62, evenness= 0.74; Prudhoe: H' = 1.62, evenness= 0.77). Nest density, nest age, nesting success, and nest initiation Observers discovered and monitored 184 nests of 18 species from 9 June to 10 July, 2010. Semipalmated Sandpiper, Lapland Longspur, and Pectoral Sandpiper nests accounted for the majority (58%) of those found (Table 2). Most nests were discovered during rope-drag nest search visits (96 of 184, 52%). Sixty-seven nests (36%) were discovered using the single-person search technique. Twenty-one were found incidentally. The average number of nests found in each study plot was 12.8 with a range of 7 to 17. Overall nest density was 125.8 ± 7.23 SE nests / km2 at Ikpikpuk (Table 2) compared to 93.3 ± 10.4 SE at Prudhoe Bay. Overall nest densities were higher at Ikpikpuk compared to Prudhoe Bay ( T 22 = 2.57, P = 0.02). Semipalmated Sandpipers had a significantly higher nest density at Ikpikpuk compared to Prudhoe Bay ( T 22 = 2.83, P = 0.01) but no other individual species comparisons indicated any significant differences in densities between sites. For breeders with precocial young, most nests were found in the incubation stage (124 of 184, 66%), with 24 other nests found during the laying stage and two nest discovered just after nest activity terminated. For the one species with semi-precocial young (Arctic Tern), two nest were found in the incubation stage and the other was discovered in the laying stage. For the two breeders with altricial young (Lapland Longspurs, Savannah Sparrows), most nests were found during incubation (23 of 31; 74%), seven were found during laying, and one during the nestling stage. 8 Among all species, 100 nests successfully hatched / fledged and 59 failed. We were unable to reliably assess the fate of 15 nests because there was not enough evidence or contradictory evidence at the nest sites. We were also unable to determine the fate of 10 nests because they were still active at the end of the field season. Nest predation was the most important cause of nest failure accounting for 54 of 59 (92%) of failed nests. Other sources of nest failure were abandonment for unknown reasons (n = 2), failure due to infertile eggs (n = 1), and to trampling likely by caribou (n = 2). For the individual species comparisons of inter-specific daily survival rate (DSR), we only detected a significant difference between longspurs and Semipalmated Sandpipers with longspurs having a significantly lower survivorship ( X 12 = 7.66, P = 0.006; Table 3). For the between species group comparison, we only detected a significant difference between passerines having lower survivorship compared to shorebirds ( X 12 = 4.56, P = 0.03; Table 3). For both individual species DSR comparisons to Prudhoe Bay (restricted to Lapland Longspur, Semipalmated and Pectoral Sandpipers for sample size) and for species groups, we found no differences for any comparison (P > 0.05; Fig. 3). We determined nest age and nest initiation dates (via forward or back calculations) for the majority of discovered nests (176 of 184; 96%) using the following methods in order of importance: egg flotation (n = 54), observed hatch (n = 81), incomplete clutch (n = 21), nestling age (passerines only; n = 5), and a combination of two of the above methods (n = 15). Mean nest initiation dates ranged from 8 June for Willow Ptarmigan (Lagopus lagopus; n = 3) to 19 June for Red-necked Phalarope (Phalaropus lobatus; n = 4; Table 4). Compared to Prudhoe Bay, nest initiation dates for all three species with an adequate sample size at both sites (n ≥ 10) were significantly different between years with initiation dates trending earlier at Prudhoe Bay (Lapland Longspur: Z = 5.03, P < 0.001; Pectoral Sandpiper: T 42 = 2.20, P = 0.03; Semipalmated Sandpiper: Z = -5.41, P < 0.001; Fig. 4). Similarly, for shorebirds and all species combined, nest initiation dates were significantly earlier at Prudhoe Bay compared to Ikpikpuk (shorebirds: T 132 = 2.80, P = 0.006; all species: T 163 = 6.10, P < 0.001). Nest predator identification We monitored 35 nests of six shorebird species and one passerine species with 15 Reconyx PC90 camera systems from 12 June to 13 July for a total of 408 observation days (Fig. 5; Table 5). Nests were monitored with cameras throughout the study area although most camera-monitored nests were in the ASDN study plots (Fig. 6). Fifteen nests successfully hatched / fledged, 13 were predated, six were of unknown fate, and one nest was still active at the end of the season when the camera was removed. Of the 13 nests that were predated, images of nest predators were definitely captured at six nests (four arctic ground squirrel [Spermophilus parryii] and two arctic fox; Table 5). For two nests we recorded only one image of the potential predator (arctic ground squirrel in both cases). Because the images did not show the squirrels at the nest or with egg / young, we could not definitely confirm these as predation events. However, based on timing, these appear to be the likely predators. At three nests, potential predators (all arctic ground squirrels) were recorded by the cameras but the time these events were recorded did not correspond to the time of predation based on nest visits. It is possible that these events were post-predation visits to the nests (or area near the nests) or they were actual predation events and either the cameras had an erroneous time setting or the observer recorded the incorrect information on the data forms. To be conservative, we can only consider these events as “possible predation events”. At two predated 9 nests, the cameras were not triggered so no images were taken. Based on the camera evidence, arctic ground squirrels appear to be the most important nest predator at this site (Table 5, Fig. 5). All arctic ground squirrel and one of the two arctic fox predation events occurred diurnally (between noon and 19:00; Table 6). All of the recorded predation events occurred during the mid-late period of the nesting season (Table 6). Nest predator abundance Five species of potential nest predators were detected during timed point-count surveys. The most numerous detections were of Glaucous Gulls and Parasitic Jaegers (Table 7). There were fewer total predator detections at Ikpikpuk compared to Prudhoe Bay (Ikpikpuk: mean = 2.97 ± 0.49; Prudhoe: mean = 3.81 ± 1.03 SE), however this difference was not statistically significant ( T 22 = -1.37, P = 0.18; Fig. 7). Likewise, for individual species comparisons for which we had adequate data (Glaucous Gulls, Parasitic, and Long-tailed Jaegers), we detected no differences in abundance between sites. However, ravens were notably absent from Ikpikpuk while the reverse was true for Arctic ground squirrels (Table 7). We detected no lemming-dependent species (Snowy owls or Pomarine Jaegers) on incidental counts although they were detected during informal daily species surveys (Table 1). Microtine activity and abundance Microtines were detected only once (likely a vole) during 161.2 hrs of observation time while visiting our study plots (0.003 ± 0.002 SE lemmings / 30min). At Prudhoe Bay, microtines were detected at similarly low levels (0.006 ± 0.005 SE lemmings / 30min) thus 2010 appeared to be a “low” lemming year at both sites. Habitat use, vegetative concealment, snow cover, and weather assessment Nests were found in nine of 15 landform types. Most nests (109 of 183, 60%) were located in low-center polygon landform types (Unit 3: low-centered polygons, rim-center relief >0.5 m and Unit 4: low-centered polygons, rim-center relief ≤0.5 m; Fig. 8). See Walker (1980) for detailed description of these landforms. Most nests in plots were located in the “lowland wet meadow” ecotype (116 of 153; 75.8%; Fig. 9) with all nests except for two in one of four “meadow” ecotypes. An Arctic Tern nest on a mat of vegetation within a pond was classified as “lowland lake” and one Black-bellied Plover (Pluvialis squatarola) nest occurred within the “upland dwarf scrub tundra” ecotype (Fig. 9). Overall nest concealment for Lapland longspurs was significantly higher than for all shorebird species with adequate sample sizes (n ≥ 10): Dunlin (Calidris alpina; T 36 = -4.46, P < 0.001), Semipalmated Sandpiper (Z = 5.28, P < 0.001), Red Phalarope (Z = -4.05, P = < 0.001), and Pectoral Sandpipers ( T 49 = 4.12, P < 0.001; Table 8). Successful longspur nests had significantly more vegetative concealment above the nest compared to depredated nests (mean successful = 70.00 ± 4.48 SE vs. mean predated: 45 ± 8.06; T 21 = 2.71, P = 0.01). For shorebirds as a group, vegetative concealment was not significantly different between successful and depredated nests (mean successful = 20.55 ± 1.72 SE vs. mean predated: 25.17 ± 4.23; T 39 = 0.55, P = 0.59). By the time we conducted our first snow cover surveys at Ikpikpuk on June 9-11, mean snow cover was just under 4% (Fig. 10). Snow melt at Ikpikpuk seemed to lag behind Prudhoe Bay to some degree since snow melt was essentially complete by June 9 (Julian date: 160) at Prudhoe Bay. Because we started snow cover surveys at Ikpikpuk five days later than at Prudhoe Bay it is difficult to compare the rate of melt between sites. However, anecdotal observations at 10 Ikpikpuk suggest that early season snow melt occurred in an exponential manner as at Prudhoe Bay (Liebezeit and Zack 2010). Upon arrival at the site we experienced a brief warm spell followed by cool temperatures until July (Fig. 11). The mean temperature at Ikpikpuk from 10 June to 13 July was 4.9°C ± 0.49 SE. During this same time period, mean wind speed was 18.25km / h ± 1.02SE coming from the ESE (124º ± 14.9SE) and relative humidity was 87.21% ± 1.49SE. Mean temperature at Prudhoe Bay during the same time period was very similar (5.10°C ± 0.66SE). At Prudhoe Bay, 2010 was a relatively cold year (during the breeding season) compared to previous years ranking as the third coldest year since 2003 so it is likely it was a “cold year” at Ikpikpuk as well. DISCUSSION We found a relatively high diversity of breeding birds at the Ikpikpuk river study site with over 31 species that breed or are likely breeders compared to Prudhoe Bay where we observed 21 breeder / likely breeders. Detection of species may have been higher at Ikpikpuk because of the 4-person crew size (vs. 2-person at Prudhoe Bay), although the Prudhoe Bay crew was able to cover a much larger study area (because of vehicle access) including some habitats (e.g. coastal) not available to the Ikpikpuk crew. Overall nest density was higher at Ikpikpuk than at other study sites sampled in recent years on the Arctic Coastal Plain to the east including other nearby sites in the NE NPR-A (Liebezeit et al. In press, Cotter and Andres 2000). However, nest densities often vary significantly from year to year in the Arctic (Liebezeit et al. In press) so multi-year sampling at Ikpikpuk will determine whether it has consistently high nest densities compared to other sites on the Arctic Coastal Plain. We found nest predation to be the most important cause of nest failure at this site. This result is in accord with previous studies that included both the Prudhoe Bay and Kuparuk Oilfields and sites further east into the Arctic National Wildlife Refuge (Troy 2000, Liebezeit et al. 2009). Nest predation has also been reported to be the most significant cause of nest failure for passerines, shorebirds, and waterfowl at many other locations within the arctic coastal plain (Custer and Pitelka 1977, Quinlan and Lehnhausen 1982, Helmers and Gratto-Trevor 1996). We found other causes of nest failure to be minimal this season. However, other researchers have found inclement weather to cause large-scale nest failure in some years (Barry 1962). Caribou trampling has also been suspected to be an important cause of nest failure in the Prudhoe Bay region in some years (D. Troy pers. comm.). Daily survival rate (nesting survivorship) was generally higher at Ikpikpuk compared to Prudhoe Bay although this trend was not statistically significant. This result is similar to what we found at the nearby Teshekpuk Lake site in previous years (Liebezeit et al. In press). This provides further support of the importance of the NE NPR-A for nesting birds compared to adjacent sites to the east. As with nest densities, survivorship can vary dramatically temporally and between species in the Arctic (Liebezeit et al. 2009, In press) so multiple years of data collection at Ikpikpuk will help determine if this trend is consistent. Our predator surveys indicated that the most prevalent potential nest predators at this site were Glaucous Gulls and jaegers (Parasitic and Long-tailed). This matches what we have observed at Prudhoe Bay for years (Liebezeit et al. 2009) and also at the Teshekpuk Lake site (Liebezeit et al. In press). However, it is important to note that these surveys may be biased toward detecting avian predators because some of the most prevalent mammalian potential predators (e.g. arctic fox) have been found to be most active nocturnally (Eberhardt et al. 1982). We detected fewer predators (overall and per species) at Ikpikpuk compared to Prudhoe Bay although arctic ground squirrels were detected more often at Ikpikpuk. Two species of generalist nest predators (Common Ravens and arctic fox) were much less common at Ikpikpuk. This may 11 be because these predators are often attracted to human-altered areas, as at the Prudhoe Bay oilfield. Our camera evidence of nest predators suggests that arctic ground squirrels are the most important predator at this site. This is not what we would have expected based on our predator surveys (see previous paragraph). This finding contrasts markedly from Prudhoe Bay where arctic fox were the most important predator according to camera evidence. This finding is not totally unexpected since arctic fox have been reported to be more abundant in the Prudhoe Bay oilfield compared to surrounding areas (Burgess and Banyas 1993), likely because of the attraction to human-produced edible wastes. It is possible that some of the predators we identified with the cameras were responsible for predating more than one nest. In particular, on 3 July two nests that were within approximately 280 m were depredated within 45 min of one another by an arctic ground squirrel. Home range sizes for male arctic ground squirrels can range widely across space and time. A study in Yukon, Canada found home range size from 488-2565 m2 (Lacey and Wieczorek 2000). If we assumed a circular territory, the diameter of the territory would range from ~12-28 m. If arctic squirrel home range sizes are as small as the ones at the Yukon site, then it is not likely that the same squirrel depredated the nests in question. Lemmings were observed in low abundance at Ikpikpuk in 2010; the same was true for Prudhoe Bay. Likewise, Snowy Owls and Pomarine Jaegers did not appear to be in higher numbers this season. These species are thought to prey almost exclusively on lemmings and are typically more abundant and nest with higher frequency in high lemming years (Parmelee 1992, Wiley and Lee 2000). Overall nesting habitat use at this site was dominated by lowland wet meadow habitats comprised mainly of the low center polygon landform type. Although in this report we do not quantify habitat use versus availability, most shorebirds, which are the predominant nester at this site, typically select wetter tundra habitats (Brown et al. 2007, Liebezeit et al. In press). Thus this initial examination of habitat use is consistent with previous findings. In our final report we will examine nesting habitat preference per species and species group. At Prudhoe Bay, lowland wet meadow ecotype was also the most important habitat for nesting although high-center polygons and strangmoor were the dominant landform type at that site. Lapland Longspur nests with higher vegetative concealment were less likely to be depredated. As one may expect, nest predators are often less successful at finding more cryptically concealed nests than more exposed ones (Bowman and Harris 1980). However, this trend was not observed for shorebirds (overall) nor was it documented at Prudhoe Bay for any species (Liebezeit and Zack 2010). Lapland Longspur nest concealment was significantly higher compared to Semipalmated and Pectoral Sandpiper nests. This may be due to their differing nest site selection strategies. Longspurs tend to nest at the base of grass tussocks, on the side of ridges, or abutting polygon rims (see Rodrigues 1994) while many sandpipers nest in open scrapes. Because longspurs rear altricial young at the nest, it may be more important for them to have greater overhead concealment providing cover for the helpless young. In contrast, precocial sandpipers have cryptically marked eggs and quickly leave the nest upon hatching, thus may not require as much vegetative cover. Snow cover appeared to be higher this year in the central Arctic Coastal Plain of Alaska, compared to recent years, with high snow cover in the first days of June but then rapid melting (J. Liebezeit pers. obs.). We expected to have earlier snowmelt at Ikpikpuk compared to Prudhoe Bay since it is located more inland and summer temperatures are typically lower near the coast on the Arctic Coastal Plain. However, snow melt lagged behind Prudhoe Bay to some degree. Since temperature differences between sites were negligible, the lag in snow melt at Ikpikpuk may have been due to higher overall snow depth at this site. 12 Troy (1993) found that snowmelt is strongly correlated with nest initiation. During the short arctic breeding season, most species tend to initiate nesting as early as possible, thus the main limiting factor at this time is believed to be snow cover. Accordingly, we found that mean nest initiation dates for most species were later at Ikpikpuk compared to Prudhoe Bay. Overall, the nest initiation dates that we documented this season fall within the range found by other researchers on the North Slope (Custer and Pitelka 1977, Ashkenazie and Safriel 1979, Troy 1993). ACKNOWLEDGEMENTS We thank the Bureau of Land Management, Alaska Department of Fish and Game, the Liz Claiborne / Art Ortenberg Foundation, and the U.S. Fish and Wildlife – NMBCA grant, for providing funds to support this project. We thank Patagonia for generously donating field clothing for use by the field crew. We thank Bob Gill and Mike McCrary at 70 North, LLC for safely and timely getting us in and out of the site. Finally, and most importantly, we thank the nest monitoring field crew (Kevin Pietrzak, Anaka Mines, McKenzie Mudge, and Nicole Cook) and the camera tech (Caitlyn Bishop) for their hard work in the field. LITERATURE CITED Afifi, A.A. and V. Clark. 1998. Computer-aided multivariate analysis, Third edition. Chapman & Hall, New York. Ashkenazie, S. and U.N. Safriel. 1979. Breeding cycle and behavior of the Semipalmated Sandpiper at Barrow, Alaska. Auk 96: 56-67. Barry, T.W. 1962. Effect of late seasons on Atlantic Brant reproduction. Journal of Wildlife Management 26: 19-26. Bowman, G. B. and L. D. Harris. 1980. Effect of spatial heterogeneity on ground-nest predation. Journal of Wildlife Management 44: 806-813. Brown, S., Bart, J., Lanctot, R.B., Johnson, J.A., Kendall, S., Payer, D., and Johnson, J. 2007. Shorebird abundance and distribution on the coastal plain of the Arctic National Wildlife Refuge. Condor 109: 1-14. Brown, S., Hickey, C., Harrington, B., and Gill, R., eds. 2001. United States Shorebird Conservation Plan, 2nd ed. Manomet, Massachusetts: Manomet Center for Conservation Sciences. Burgess, R.M. and P.W. Banyas. 1993. Inventory of Arctic Fox dens in the Prudhoe Bay region, 1992. BP Exploration [Alaska], Inc. Anchorage, Alaska. Unpublished report. Cotter, P.A. and Andres, B.A. 2000. Nest density of shorebirds inland from the Beaufort sea coast, Alaska. Canadian Field-Naturalist 114: 287-291. Custer, T.W. and F.A. Pitelka. 1977. Demographic features of a Lapland Longspur population 13 near Barrow, Alaska. Auk 94: 505-525. Day, R.H. 1998. Predator population and predation intensity on tundra-nesting birds in relation to human development. Alaska Biological Research Associates, Inc. Fairbanks, Alaska. Unpublished report. Earnst, S.L., R.A. Stehn, R.M. Platte, W.M. Larned, and E.J. Mallek. 2005. Population size and trend of Yellow-billed Loons in northern Alaska. Condor 107: 289-304. Eberhardt, L.E., W.C. Hanson, J.L. Bengtson, R.A. Garrott, and E.E. Hanson. 1982. Arctic fox home range characteristics in an oil-development area. Journal of Wildlife Management 46: 183-190. Ehrlich, P.R., D.S. Dobkin, and D. Wheye. 1988. The Birder’s Handbook: A field guide to the natural history of North American birds. Fireside, Simon and Schuster, New York. Helmers, D.L. and C.L. Gratto-Trevor. 1996. Effects of predation on migratory shorebird recruitment. Transactions of the 61st North American Wildlife and Natural Resources Conference. Hintze, J. L. 2000. Number Cruncher Statistical System (NCSS), version 2000, Kaysville, UT. Hussell, D.J.T. and R. Montgomerie. 2002. Lapland Longspur (Calcarius lapponicus). In The Birds of North America, No. 656 (A. Poole and F. Gill, eds.). The Birds of North America, Inc. Philadelphia, PA. James, F.C. and H.H. Shugart, Jr. 1970. A quantitative method of habitat description. Audubon Field Notes, Vol. 24: 727-737. Johnson, D.H. 1979. Estimating nest success: the Mayfield method and an alternative. Auk 96: 651-661. Johnson, J.A., Lanctot, R.B., Andres, B.A., Bart, J.R., Brown, S.C., Kendall, S.J., and Payer, D.C. 2007. Distribution of breeding shorebirds on the Arctic Coastal Plain of Alaska. Arctic 60(3): 277-293. Johnson, S.R. and Herter, D.R. 1989. The birds of the Beaufort Sea. Anchorage: British Petroleum Exploration (Alaska), Inc. Jorgensen, T. and M. Heiner. 2003. Ecosystems of Northern Alaska. Unpublished 1:2.5 millionscale map produced by ABR, Inc., Fairbanks, AK and The Nature Conservancy, Anchorage, AK. (Available at www.nature.org/wherewework/northamerica/states/ alaska /files/aya2.pdf). Kertell, K. 1991. Disappearance of the Steller’s eider from the Yukon-Kuskokwim Delta, Alaska. Arctic 44:177-187. 14 King, J.G. and Hodges, J.I. 1979 A preliminary analysis of goose banding on Alaska’s Arctic slope. In: Jarvis, R.L., and Bartonek, J.C., eds. Management and biology of Pacific Flyway geese. Oregon State University Book Stores, Corvallis, Oregon. 176-188. Lacey and Wieczorek 2000. Territoriality and male reproductive success in arctic ground squirrels. Behavioral Ecology 12: 626-632. Larned , W., R. Stehn, and R. Platte. 2005. Eider breeding population survey, Arctic Coastal Plain Alaska. U.S. Fish and Wildlife Service, Migratory Bird Management, Anchorage, Soldotna. Liebezeit, J.R., G.C. White, and S. Zack. In Press. Breeding ecology of birds at Teshekpuk Lake: a key habitat site on the Arctic Coastal Plain of Alaska. Arctic. Liebezeit, J.R. 2010. Nest survivorship of tundra-nesting birds in relation to human development on Alaska’s North Slope – field protocols – 2010. Unpublished document. 42p. Liebezeit. And S.W. Zack. 2010. Avian habitat and nesting use of tundra-nesting birds in the Prudhoe Bay Oilfield – Long-term monitoring: 2010 annual report. Prepared by the Wildlife Conservation Society for the Bureau of Land Management, Alaska Department of Fish and Game, BP exploration (Alaska), Inc., & other interested parties/stakeholders. 37 p. Liebezeit, J.R., P.A. Smith, R.B. Lanctot, H. Schekkerman, I. Tulp, S.J. Kendall, D.M. Tracy, R.J. Rodrigues, H. Meltofte, J.A. Robinson, C. Gratto-Trevor, B.J. McCaffery, J. Morse, and S.W. Zack. 2007. Assessing the development of shorebird eggs using the flotation method: species-specific and generalized regression models. Condor 109: 32-47. Liebezeit, J.R., S.J. Kendall, S. Brown, C.B. Johnson, P. Martin, T. McDonald, D. Payer, C.L. Rea, B. Streever, A.M.Wildman, and S. Zack. 2009. Influence of human development and predators on nest survival of tundra birds, Arctic Coastal Plain, Alaska. Ecological Applications 19: 1628-1644. Mabee, T. 1997. Using eggshell evidence to determine nest fate of shorebirds. Wilson Bulletin 109: 307-313. Manolis, J.C., D.E. Andersen, and F.J. Cuthbert. 2000. Uncertain nest fates in songbird studies and variation in Mayfield estimation. Auk 117: 615-626. Martin, T.E., C. Paine, C.J. Conway, W.M. Hochachka, P. Allen, and W. Jenkins. 1997. Breeding Biology Research and Monitoring Database (BBIRD). Montana Cooperative Wildlife Research Unit. Missoula, MT. Mayfield, H.F. 1975. Suggestions for calculating nest success. Wilson Bulletin 87: 456-466. Morrison, R.I.G., McCaffery, B.J., Gill, R.E., Skagen, S.K., Jones, S.L., Page, G.W., GrattoTrevor, C.L., and Andres, B.A. 2006. Population estimates of North American shorebirds, 2006. Wader Study Group Bulletin 111:67-85. 15 NAS. 2003. Cumulative environmental effects of oil and gas activities on Alaska’s North Slope. National Research Council of the National Academies. National Academies Press, Washington D.C. Naves, L.C., R.B. Lanctot, A.R. Taylor, and N.P. Coutsoubos. 2008. How often do arctic shorebirds lay replacement clutches? Wader Study Group Bulletin 115(1): 2-9. Parmelee, D.F. 1992. Snowy Owl (Nyctea scandiaca). In The Birds of North America, No. 10. (A. Poole and F. Gill, eds.). The Birds of North America, Inc., Philadelphia, PA. Pitelka, F.A. 1974. An avifaunal review for the Barrow region and North Slope of Alaska. Arctic Alpine Research 6: 161-184. Poole, A.F., Stettenheim, P., and Gill, F.B., eds. 2003. The Birds of North America: Life Histories for the 21st century. The Academy of Natural Sciences, Philadelphia, and The American Ornithologists’ Union, Washington, D.C. Quinlan, S.E. and W.A. Lehnhausen. 1982. Arctic Fox, Alopex lagopus, Predation on nesting Common Eiders, Somateria mollissma, at Icy Cape, Alaska. Canadian Field-Naturalist 96: 462-466. Ralph, C.J., G.R. Geupel, P. Pyle, T.E. Martin, and D.F. DeSante. 1993. Handbook of field methods for monitoring landbirds. Gen. Tech. Rep. PSW-GTR-144. Albany, California: Pacific Southwest Research Station, Forest Service, U.S. Department of Agriculture. 41 p. Rodrigues, R. 1994. Microhabitat variables influencing nest-site selection by tundra birds. Ecological Applications 4: 110-116. Sauer, J. R., and B. K. Williams. 1989. Generalized procedures for testing hypotheses about survival or recovery rates. Journal of Wildlife Management 53:137-142. Stehn, R.A., Dau, C.P., Conant, B., and Butler, W.I. 1993. Decline of Spectacled Eiders nesting in western Alaska. Arctic 46: 264-277. Troy, D.M. 1993. Population dynamics of birds in the Pt. McIntyre reference area, 1981-1992. Troy Ecological Research Associates Prepared for BP Exploration [Alaska], Inc. Anchorage, Alaska. Unpublished report. Troy, D.M.1996. Population dynamics of breeding shorebirds in Arctic Alaska. International Wader Studies 8: 15-27. Troy, D.M. 2000. Shorebirds In The Natural History of an Arctic Oil field, Development and the Biota (J.C. Truett and S.R. Johnson, eds.). Academic Press, San Diego, CA. Walker, D.A., K.R. Everett, P.J. Webber, and J. Brown. 1980. Geobotanical atlas of the Prudhoe Bay region, Alaska. United States Army Corps of Engineers. Cold Regions Research and Engineering Laboratory. CRREL report 80-14. Hanover, NH. 16 Whitaker, J.O. 1996. National Audubon Society Field Guide to North American Mammals. National Audubon Society. Random House, Inc. White, G.C. and K. P. Burnham. 1999. Program MARK: Survival estimation from populations of marked animals. Bird Study 46 Supplement, 120-138. Wiley, R.H., and D.S. Lee. 2000. Pomarine Jaeger (Stercorarius pomarinus). In The Birds of North America, No. 483. (A. Poole and F. Gill, eds.). The Birds of North America, Inc., Philadelphia, PA. Zar, J.H. 1999. Biostatistical analysis. 4th edition. Prentice Hall, NJ. 17 Figure 1. The Ikpikpuk River study site and study plot locations, National Petroleum Reserve, Alaska, 2010. “ASDN” = Arctic Shorebird Demographics Network. 18 Aerial view of WCS Ikpikpuk camp and field site in early June shortly after arrival. Photo: C. Smith WCS Ikpikpuk camp. Photo: C. Bishop WCS field assistants (Anaka Mines & McKenzie Mudge) conducting field work on nest monitoring plot 4. Photo: J. Liebezeit Weather station at Ikpikpuk camp. Photo: J. Liebezeit Kevin Pietrzak, crew leader of the nest monitoring crew. Photo: McKenzie Mudge Semipalmated Sandpiper, the most common nester at Ikpikpuk. Photo: N. Cook Figure 2. Pictures from the Ikpikpuk River study site, National Petroleum Reserve - Alaska. 19 1 Nest daily survival rate 0.99 0.98 0.97 0.96 0.95 0.94 0.93 Lapland Longspur Semipalmated Sandpiper Pectoral Sandpiper 0.92 0.91 0.9 Prudhoe Bay Ikpikpuk Figure 3. Daily survival rates (± 1 SE) for the three most common nesting species at the Ikpikpuk River and Prudhoe Bay Oilfield study sites in 2010, Arctic coastal plain, Alaska. 165 Julian date 163 161 159 157 155 Lapland Longspur Semipalmated Sandpiper Pectoral Sandpiper 153 Ikpikpuk Prudhoe Bay Figure 4. Mean nest initiation date (± 1 SE) for the three most common nesting birds at the Ikpikpuk River and Prudhoe Bay Oilfield study sites in 2010, Arctic coastal plain, Alaska. 20 Reconyx PC90 camera system. Photo: C. Bishop Caitlyn Bishop (camera technician) and Vitek Jirinec checking one of the Reconyx cameras. Photo: C. Smith Arctic fox raiding a Semipalmated Sandpiper nest, July 10, 2010 at 02:56. Arctic ground squirrel eating a Red Phalarope egg, July 7, 2010 at 15:15. Figure 5. Photographic display of the remote camera system used to monitor tundra-nesting birds for predation events and two images of recorded predation events, Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. 21 Figure 6. Location of camera-monitored nests and identified predators, Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. 22 4 other predators Arctic Fox Avg. # preds. detected / 30 min. 3.5 Common Raven Long-tailed Jaeger 3 Parasitic Jaeger Glaucous Gull 2.5 2 1.5 1 0.5 0 Ikpikpuk Prudhoe Bay Most common potential nest predators Figure 7. Average number of potential nest predators (± 1 SE) detected in or near study plots / 30 min survey period at the Ikpikpuk River and Prudhoe Bay Oilfield study sites, Alaska Coastal Plain, Alaska, 2010. “Other predators” include Red Fox at both sites and Arctic ground squirrels at Ikpikpuk only. 80 Number of nests 70 60 50 40 30 20 10 0 Unit 0 Unit 2 Unit 3 Unit 4 Unit 5 Unit 7 Unit 8 Unit 9 Unit A Landform type Figure 8. Number of nests found in each landform type within study plots at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Unit 0 = non-patterned ground; Unit 2 = high-centered polygons (≤ 0.5m center-trough relief); Unit 3 = Low-centered polygon (rim-center relief ≤0.5m); Unit 4 = Low-centered polygon (rim-center relief >0.5m); Unit 5 = Mixed high and low centered polygons; Unit 7 = Strangmoor and/or disjunct polygon rims; Unit 8 = Hummocky terrain; Unit 9 = Reticulate-patterned ground; Unit A: Alluvial Floodplain. 23 Number of nests 120 100 80 60 40 20 0 Lowland lake Lowland Moist Lowland Wet Riverine Moist Riverine Wet Upland Dwarf Meadow Meadow Meadow Meadow Scrub Tundra Habitat Class Figure 9. Number of nests found in each ecotype class (local-scale ecosystems) as defined by Jorgensen and Heiner (2003) at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. 18 Mean snow cover (%) 16 2 R = 0.1112 14 12 10 8 6 4 2 0 158 163 168 173 178 Julian date Figure 10. Mean snow cover (%) for survey dates on all plot location fitted with linear trend, Ikpikpuk River study site, National Petroleum Reserve – Alaska, 2010. 24 o Mean daily temperature ( C) 20 18 16 14 Ikpik average temp (°C) PB average temp (°C) 12 10 8 6 4 2 0 6/9/2010 6/14/2010 6/19/2010 6/24/2010 6/29/2010 7/4/2010 7/9/2010 7/14/2010 Date Figure 11. Mean daily temperatures (°C ± 1 SE) during the core breeding season (10 June to 13 July) at the Ikpikpuk River study site, National Petroleum Reserve Alaska, and the Prudhoe Bay oilfield study site, 2010. 25 Table 1. Bird diversity and relative abundance at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Abundance* Species Species Abundance* U Red-throated Loon (Gavia stellata) C Pacific Loon (Gavia pacifica) Yellow-billed Loon (Gavia adamsii) Red-necked Grebe (Podiceps grisegena) Tundra Swan (Cygnus columbianus) Cackling Goose (Branta hutchinsii) Brant (Branta bernicla) Greater White-fronted Goose (Anser albifrons) Snow Goose(Chen caerulescens) C F F R F A R A R R Green-winged Teal (Anas crecca) F Greater Scaup (Aythya marila) King Eider (Somateria spectabilis) F U Spectacled Eider (Somateria fischeri) Long-tailed Duck (Clangula hyemalis) Red-breasted Merganser (Mergus serrator) Northern Harrier (Circus cyaneus) Golden Eagle (Aquila chrysaetos) Bald Eagle (Haliaeetus leucocephalus) Merlin (Falco columbarius) C R Ruddy Turnstone (Arenaria interpres) Dunlin (Calidris alpina) Pectoral Sandpiper (Calidris melanotos) Semipalmated Sandpiper (Calidris pusilla) Stilt Sandpiper (Calidris himantopus) Long-billed Dowitcher (Limnodromus scolopaceus) Red Phalarope (Phalaropus fulicaria) Red-necked Phalarope (Phalaropus lobatus) Long-tailed Jaeger (Stercorarius longicaudus) Parasitic Jaeger (Stercorarius parasiticus) Pomarine Jaeger (Stercorarius pomarinus) Glaucous Gull (Larus hyperboreus) R A A A U C A A C C U A F Sabine’s Gull (Xema sabini) R C R R R A Willow Ptarmigan (Lagopus lagopus) Sandhill Crane (Grus canadensis) Black-bellied Plover (Pluvialis squatarola) R A R Peregrine Falcon (Falco peregrinus) Rock Ptarmigan (Lagopus mutus) F Bar-tailed Godwit (Limosa lapponica) Northern Pintail (Anas acuta) Northern Shoveler (Anas clypeata) American Golden-plover (Pluvialis dominica) Semipalmated Plover (Charadrius semipalmatus) Whimbrel (Numenius phaeopus) C R Arctic tern (Sterna paradisaea) Short-eared Owl (Asio flammeus) Snowy Owl (Bubo scandiacus) Yellow Wagtail (Motacilla flava) Savannah Sparrow (Passerculus sandwichensis) White-crowned Sparrow (Zonotrichia leucophrys) Lapland Longspur (Calcarius lapponicus) Repoll sp. (Carduelis spp) A R R R C R A F C *(A) Abundant: Easy to find in large numbers on any given day in a variety of habitats; (C) Common: Easy to find in good numbers on any given day in suitable habitat; (F) Fairly common: Likely to find in small numbers on most days in suitable habitat; (U) Uncommon: Possible to find in small numbers on one in four days in suitable habitat; (R) Rare: Seldom found in any numbers even in suitable habitat. (X) Extremely rare: Found only in some years and only one or two occurrences in the season. 26 Table 2. Number of discovered nests and nest density for each species from the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Species Species Code Discovered Nestsa Nest densityb (nests/km2) Semipalmated Sandpiper (Calidris pusilla) SESA 56 (45) 36.7 Lapland Longspur (Calcarius lapponicus) LALO 29 (27) 21.7 Pectoral Sandpiper (Calidris melanotos) PESA 22 (17) 14.2 Greater White-fronted Goose (Anser albifrons) GWFG 19 (17) 14.2 Red Phalarope (Phalaropus fulicaria) REPH 15 (14) 11.7 Dunlin (Calidris alpina) DUNL 10 (7) 5.8 Long-billed Dowitcher (Limnodromus scolopaceus) LBDO 8 (2) 5.0 Red-necked Phalarope (Phalaropus lobatus) RNPH 4 (4) 3.3 Black-bellied Plover (Pluvialis squatarola) BBPL 4 (3) 2.5 Willow Ptarmigan (Lagopus lagopus) WIPT 4 (3) 2.5 Arctic Tern (Sterna paradisaea) ARTE 3 (3) 2.5 American Golden-plover (Pluvialis dominica) AMGP 2 (1) 0.8 Savannah Sparrow (Passerculus sandwichensis) SAVS 2 (1) 0.8 Bar-tailed Godwit (Limosa lapponica) BARG 1 (1) 0.8 Long-tailed Duck (Clangula hyemalis) LTDU 1 (1) 0.8 Northern Pintail (Anas acuta) NOPI 1 (1) 0.8 Greater Scaup (Aythya marila) GRSC 1 (1) 0.8 Rock Ptarmigan (Lagopus mutus) ROPT 1 (1) 0.8 184 (153) 125.8 Total a ( ) = Nests found within the plot boundaries Nest density calculated from nests excludes off- plot nests and second nesting attempts (Lapland Longspur: 10KWP044; Semipalmated Sandpiper: 10KWP049; n = 151). b 27 Table 3. Summary of daily survival rate (DSR) and Mayfield nesting success estimates of tundrabreeding birds at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. na Mayfieldb Daily survival ratec SE Statistically different from (at α 0.05) Semipalmated Sandpiper 45 0.801 0.989 0.004 LALO Lapland Longspur 28 0.358 0.954 0.012 SESA Pectoral Sandpiper 17 0.583 0.976 0.010 none Greater White-fronted Goose 16 0.608 0.980 0.008 none Red Phalarope 14 0.655 0.978 0.011 none Dunlin 7 0.649 0.980 0.014 - Long-billed Dowitcher 6 0.554 0.973 0.019 - Phalaropes 18 - 0.974 0.011 none Waterfowl 19 - 0.975 0.009 none Passerines 29 - 0.956 0.011 shorebirds Shorebirds 98 - 0.981 0.004 passerines Shorebirds, passerines, waterfowl 145 - 0.976 0.003 none Species Individual species Species groups a This estimate excludes nests outside of the study plots and nests that failed due to human disturbance. Only included individual species estimates if n ≥5. b All estimates are for incubation period only except passerines (Lapland Longspurs, Savannah Sparrows) which includes both incubation and nestling periods. C Program MARK constant daily survivorship model used to calculate daily survival rate and corresponding standard error estimates. 28 Table 4. Nest initiation dates of tundra-nesting birds at the Ikpikpuk River study site, National Petroleum Reserve, Alaska, 2010. Minimum Maximum 28 Mean initiation date ± 1 SE 10 June ± 0.92 1 June 23 June Semipalmated Sandpiper 21 10 June ± 0.39 2 Jun 22 June Pectoral Sandpiper 23 12 June ± 0.67 7 June 20 June Red-necked Phalarope 4 19 June ± 2.50 14 June 24 June Red Phalarope 15 12 June ± 1.10 5 June 23 June Dunlin 10 10 June ± 1.35 7 June 21 June Greater White-fronted Goose 17 9 June ± 0.54 5 June 13 June Long-billed Dowitcher 8 10 June ± 1.49 6 June 17 June Black-bellied-plover 4 15 June ± 0.65 13 June 16 June Willow Ptarmigan 3 8 June ± 1.53 6 June 11 June American Golden-plover 2 18 June ± 6.00 12 June 24 June Arctic Tern 2 12 June ± 0.50 11 June 12 June Savannah Sparrow 2 14 June ± 0.50 13 June 14 June Bar-tailed Godwit 1 24 June - - Northern Pintail 1 19 June - - Species* n Lapland Longspur * This estimate includes off-plot nests but excludes nests of unknown age and likely second nesting attempts (see Table 2). 29 Table 5. Summary of camera-monitored nest information at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Prey species Semipalmated Sandpiper 1 Number of nests monitored 10 Lapland Longspur 10 Pectoral Sandpiper 4 Red Phalarope 4 Camera monitor days 142 184 20 32 Fate Definite predator 4 Hatch 4 Predation 2 Unknown 7 Fledge 3 Predation Likely predator ARFO1 AGSQ AGSQ, ARFO AGSQ1 AGSQ 3 Unknown 1 Predation 2 Hatch 2 Predation Dunlin 3 12 2 Hatch 1 Predation Red-necked Phalarope 3 12 2 Predation 1 Unknown Long-billed Dowitcher 1 6 Undetermined TOTAL 34 408 15 hatch/fledge 13 Predation 6 Unknown 1 Undetermined ARFO = Arctic Fox; AGSQ = Arctic ground squirrel 30 Possible predator AGSQ AGSQ AGSQ AGSQ AGSQ 4 AGSQ 2 ARFO 2 AGSQ 3 AGSQ Table 6. Date and time of predation events, Ikpikpuk River study site, National Petroleum Reserve, Alaska, 2010. Date of predation1 10CJS019 Predator species AGSQ 7/5/10 Time of predation1 15:022 Red Phalarope 10CJS048 AGSQ 7/7/10 13:32 Semipalmated Sandpiper 10MLM003 AGSQ 6/24/10 18:52 Lapland Longspur 10VJ002 AGSQ 6/20/10 18:45 – 19:48 Red-necked Phalarope 10VJ008 AGSQ 7/7/10 15:12 – 15:15 Lapland Longspur 10VJ011 AGSQ 6/19/10 12:08 Red Phalarope 10VJ059 AGSQ 7/3/10 13:18 Dunlin 10VJ065 AGSQ 7/3/10 14:01 Pectoral Sandpiper 10VJ053 AGSQ 7/4/10 14:35 – 14:36 Semipalmated Sandpiper 10VJ086 ARFO 7/10/10 14:563 Lapland Longspur 10VJ096 ARFO 7/8/10 03:01 Prey species Nest ID Semipalmated Sandpiper 1 includes “likely” or “possible” predators. AGSQ visit also recorded the next day (7/6/10) at 10:27-28 3 ARFO visit also recorded the next day (7/11/10) at 06:54 2 31 Table 7. Average number of all potential predators (and noted absences of other key predators) recorded during predator surveys for four time periods on and near study plots at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Earlya Speciesb Mean ± 1 SE / 30 min count Middle Mean ± 1 SE / 30 min count Late Season Mean ± 1 SE / 30 min count Mean ± 1 SE / 30 min count 32 Glaucous Gull 1.50 ± 0.44 1.58 ± 0.45 1.67 ± 0.41 1.58 ± 0.38 Parasitic Jaeger 0.67 ± 0.40 0.92 ± 0.29 0.42 ± 0.29 0.67 ± 0.17 Pomarine Jaeger 0 0 0 0 Long-tailed Jaeger 0.25 ± 0.18 0.58 ± 0.23 0.25 ± 0.13 0.36 ± 0.10 Jaegerc 0.92 ± 0.47 1.50 ± 0.31 0.67 ± 0.33 1.03 ± 0.22 0 0.50 ± 0.26 0.50 ± 0.23 0.33 ± 0.15 0.08 ± 0.08 0 0 0.03 ± 0.03 Arctic fox 0 0 0 0 Common Raven 0 0 0 0 Snowy Owl 0 0 0 0 Arctic gr. squirrel Red fox a Early = 6/20 and before, Middle = 6/21 to 7/5, Late = 7/6 and after, Season = all time periods. Total sample size for each period = number of study plots (12). Total detections: Glaucous Gull (n = 57), Parasitic Jaeger (n = 24), Long-tailed Jaeger (n = 13), Arctic Ground Squirrel (n = 12), and Red fox (n = 1). c Combines all jaeger species b 32 Table 8. Summary of overhead nest concealment for the most common species (n ≥ 10) and species groups at the Ikpikpuk River study site, National Petroleum Reserve - Alaska, 2010. Species n Mean concealment ± 1 SE Dunlin 10 18.00 ± 3.27 Lapland Longspur 28 56.61 ± 5.42 Pectoral Sandpiper 23 27.83 ± 3.92 Red Phalarope 15 19.33 ± 3.58 Semipalmated Sandpiper 56 22.14 ± 2.32 Shorebirds 123 21.30 ± 1.50 Passerines 30 59.17 ± 5.36 Phalaropes 19 21.58 ± 3.27 33
