Study Area and Site Selection

Study sites were located in the Wyoming Basin Ecoregion in southeastern Wyoming. The Wyoming Basin is an area of transition between prairie grasslands to the east and sagebrush steppe to the west (Chapman et al. 2004). The region is characterized by rolling hills with some rocky ridges. Vegetation varies primarily among mixed-grass prairie, sagebrush steppe, and salt desert shrub habitats based on topography, local soil composition, and precipitation (Shiflet 1994). Our surveys were restricted to shortgrass and mixed-grass prairie habitat, where common plant species included grama and buffalo grasses (Bouteloua spp.), sageworts (Artemisia spp.), buckwheat (Eriogonum spp.), western wheatgrass (Pascopyrum smithii), Sandberg's bluegrass (Poa secunda), and prairie Junegrass (Koeleria macrantha). Elevation ranged from 1,980 to 2,530 m. Livestock grazing is common and widespread in the Wyoming Basin, and all sites were grazed by cattle using a seasonal rotation grazing system. Sites were a mix of public and private lands. Stocking rates on public lands ranged from 1.6–5.3 ha per animal unit month. Stocking rates on private lands were unavailable but appeared comparable to those on public lands.

In 2011, we selected 2 wind farms, PacifiCorp's Seven Mile Hill (SM) and High Plains/McFadden Ridge (HP) based on the criteria of (1) a minimum of 2 years post-construction to minimize quantifying shorter-term construction-related effects; and (2) presence of grassland habitat. In 2012, we replaced SM with a wind farm with more grassland, PacifiCorp's Dunlap Ranch (DR). Wind farms all used GE 1.5 MW wind turbines, but they varied in age, size, and production capacity (Table 1). Wind farm area was calculated using the boundaries delineated by the facility operator, PacifiCorp, for the turbine build-out at the time of our study. Our preliminary analysis in 2011 of Horned Lark nests indicated a uniformly low survival rate of 6% across the 500 m distance surveyed from wind turbines. We therefore added 2 undeveloped sites in 2012 to estimate avian productivity in areas independent of wind farms and paired these reference sites with HP and DR by calculating the range of values for a suite of geographic and ecological parameters across each wind farm using ArcGIS 10 (ESRI 2011; Appendix Table 6). We generated a list of locations within 32 km of each wind farm with parameter values that fell within the range of values observed for each wind farm. The list of locations was reduced by eliminating areas on private property and those <25 ha. To maintain independence between sites, we eliminated locations closer than 5 km to one another based on the largest average home range of a terrestrial nest predator in our system (coyote [Canis latrans]; Mills and Knowlton 1991). We selected two 26 ha reference sites, Control-High Plains (CHP) and Control-Dunlap Ranch (CDR), at random from the remaining candidate sites.

TABLE 1.

Age, size, and number of turbines for wind farm study sites in southeastern Wyoming, 2011–2012.

Nest Monitoring

We conducted nest searching and monitoring during May–July 2011 at HP and SM and May–July 2012 at HP, DR, CHP, and CDR. Nest searching effort was standardized between wind farms and reference sites. Reference sites were searched in their entirety. At wind farms, areas of grassland habitat were surveyed by walking 500 m transects perpendicular to strings of turbines. Nest searching was conducted primarily by rope-dragging, which entailed pulling a 30 m rope along the ground between 2 individuals walking parallel to one another, as well as haphazard and systematic walking and behavioral observations (Winter et al. 2003). Incubating or brooding birds were flushed from the nest due to the disturbance caused by the approaching rope and/or searchers. Nest locations were recorded using a GPS unit (±4 m accuracy; Garmin Etrex Venture HC, Garmin, Olathe, KS). Nests were flagged in a random direction by placing a surveyor pin flag and a small spot of spray paint on the ground at 10 and 30 m from the nest (Johnson 2010). Nests were visited every 1–4 days until nests failed or fledged. We concluded that fledging occurred if we observed (1) fledglings of appropriate age nearby; (2) adults with food <10 m from the nest; (3) fecal material on the rim of the nest; or (4) nestlings present within 2 days of fledging age. Nests that fledged one or more young were considered successful (Martin and Geupel 1993). Categorizing nests with nestlings present within 2 days of fledging as successful may result in higher estimates of nest success and number of fledglings than nests visited more frequently. Because we applied the same approach across our study area, however, we expected no systemic bias in comparing nest success or number of fledglings within our study.

Reproductive Metrics

Clutch size can reflect maternal effects (e.g., female quality and investment) and local environmental conditions, such as food availability and predation risk (Zanette et al. 2011, Sofaer et al. 2013, Hua et al. 2014). We recorded the clutch size for all nests observed during the incubation stage on 2 or more consecutive visits. Nestling mass can be positively correlated with post-fledging survival (Suedkamp Wells et al. 2007, Greño et al. 2008, Schwagmeyer and Mock 2008), and mass can also represent parental efforts in nestling provisioning (Zanette et al. 2011). Nestling mass is determined in part by genetics, however, with larger parents producing larger offspring (Garnett 1981). We isolated environmental effects by evaluating mass adjusted for structural size, henceforth called size-adjusted nestling mass. We measured nestling mass, tarsus length, and wing chord. Variability was minimized during this period of rapid growth by measuring broods on the day before pin-break between 1030 and 1330 hr. Based on nests with known hatch and pin-break dates, Horned Lark (4.02 ± 0.04 days [mean ± SE], n = 21) and McCown's Longspur (4.00 ± <0.01 days, n = 9) pin-break seems to be a reasonable proxy for age. We estimated the ages of broods with unknown hatch date by comparing feather development with that of known-age broods. Brood age was determined based on the most-developed nestling. Tarsus length and wing chord were measured using digital calipers (to 0.1 mm). Mass (to 0.01 g) was measured using an ABCplus Series digital scale (Adam Equipment Co., Dansbury, Connecticut).

Few nests failed due to causes other than predation, so we limited analysis of the daily survival rate of nests to those nests that either survived or failed due to predation. We estimated the number of young fledged from successful nests as the number of nestlings recorded in the nest within 2 days of fledging (Martin and Geupel 1993).

Nest Site-Scale Habitat Metrics

To account for potential effects of microhabitat on reproductive success, we measured vegetative habitat characteristics within a 5 m radius of each nest that previous studies found to be associated with grassland bird habitat selection (Fisher and Davis 2010) and/or nesting success (Winter et al. 2005). After the completion of each nesting attempt, a modified 50 × 30 cm Daubenmire quadrat (Daubenmire 1959) was placed over the nest and 5 m from the nest in each of the cardinal directions. At each sampling point (north, south, east, west, center), we estimated vegetation cover, height, and density. We visually estimated percent ground cover to the nearest 5% within each Daubenmire quadrat for the following classes: grass, forb, shrub, standing dead vegetation, litter, and bare ground (adapted from Winter et al. 2000, Best et al. 1997). We combined grass, forb, shrub, and standing dead vegetation to represent total vegetative cover. We recorded height by visually estimating the height at which 80% of vegetation was growing below and then measured that height using a ruler (Stewart et al. 2001, Fisher and Davis 2010). We recorded relative vegetation density at the center of each Daubenmire quadrat as the number times that vegetation touched a Wiens pole (Wiens 1969) within 10 cm height increments. Because our vegetation was relatively short, we recorded null vegetation density values at heights above 20 cm for the vast majority of nests and therefore used estimates of vegetation density for the first 2 height increments, 0–10 cm and 10–20 cm, in the analyses. We averaged the values of cover, height, and density across the 5 sampling points for each nest.

Neighborhood-Scale Habitat Metrics

Habitat composition and configuration at scales greater than an individual breeding territory have been predictive of nest success for some grassland species (Greenwood et al. 1995, Herkert et al. 2003, Skagen et al. 2005, but see Winter et al. 2005). We defined an area ∼3 times the size of a large territory as a neighborhood. Based on previously reported territory sizes of Horned Lark and McCown's Longspur in similar habitat in Wyoming and Colorado, we estimated a neighborhood of 4.8 ha (Beason 1995, With 2010). We delineated the neighborhood of each nest using a 124 m radius circular buffer and digitized the land cover within this area at a 1:3,000 scale using Bing Aerial Maps (available through ArcGIS Online). We designated 6 land cover classes: grassland, shrubland, riparian vegetation, developed, reclaimed grassland, and water/ephemeral water. We considered land to be developed if it consisted of a maintained surface (e.g., gravel roads were categorized as developed but unmaintained 2-tracks were not). We classified areas that underwent grading, contouring, and reseeding after construction disturbance as reclaimed grassland. Using this land cover layer, we calculated grassland area, the density of grassland edge, and distance to nearest shrubby edge in each neighborhood using ArcGIS 10 and Fragstats 4 (McGarigal et al. 2012).

Wind Energy Development Metrics

We quantified wind energy development for each nest using a variety of metrics: (1) turbine density within 500 m, 1 km, 2 km, and 5 km; (2) distance to nearest turbine; (3) distance to developed edge; (4) area developed in the neighborhood; and (5) area reclaimed in the neighborhood. We calculated distance to nearest turbine and turbine density using 2010 Federal Aviation Administration turbine locations for the state of Wyoming (USFWS 2011). We estimated the distance to the nearest developed edge, amount of developed surface area, and amount of reclaimed surface area in the neighborhood of each nest using our digitized land cover layer in ArcGIS 10.

Statistical Analyses

Wind Farm vs. Reference Sites

Horned Lark reproductive success was not lower at wind farms than reference sites as measured by mean clutch size (P = 0.54), number of fledglings (P = 0.98), size-adjusted nestling mass, and daily nest survival rate (Table 2). A post-hoc examination of the data showed weak evidence of a higher average number of Horned Lark fledglings per successful nest at wind farms than reference sites (one-tailed randomization test x̄_wind-ref = 0.5, P = 0.06; Table 2).

TABLE 2.

Sample size, mean, and standard error of nest success metrics for Horned Lark and McCown's Longspur on wind farms and undeveloped reference sites in southeastern Wyoming in 2011 and 2012. The sampling unit of clutch size, daily nest survival rate, and number of fledglings (per successful nest) are nests. Nestling and nest sample sizes are given for size-adjusted nestling mass.

No measures of McCown's Longspur reproductive success differed between wind farm and reference sites, including mean clutch size (P = 0.38), number of fledglings (P = 0.42), size-adjusted nestling mass, and daily nest survival rate (Table 2).

Within Wind Farms

Nests were located across a range of observed values for development, nest-site, and neighborhood-scale habitat characteristics, with Horned Lark tending to nest closer to turbines and developed edges and in areas with higher amounts of developed and reclaimed surfaces than McCown's Longspur (Table 3). The best-supported models of nest success (those within 2 AIC_c units of the top model) varied by species and response variable (Table 4 and 5). Many of the top-ranked models, however, did not predict a directional response in nest success, with 95% CIs of the slope that crossed zero. Additionally, many of the top-ranked models were uninformative, with AIC_c scores within 2 units of the top-ranked model resulting from the addition of an uninformative predictor to the top-ranked model (Arnold 2010). Henceforth, we report only informative models that were positively or negatively related to nest success (see Appendix Table 9 and 10 for the slope and 95% CIs of nest success estimated by each model of wind energy infrastructure).

TABLE 3.

Mean ± standard error and ranges of predictor variables for nests within 500 m of a turbine in southeastern Wyoming, 2011–2012.

TABLE 4.

Best-supported models (ΔAIC_c < 2.00) of nest success for Horned Lark at wind farms in southeastern Wyoming, 2011–2012, ranked based on the difference from the top model in Akaike's Criterion corrected for small sample size (ΔAIC_c). K is the number of parameters, and w_i is the model weight. The AIC_c values of the top model for each metric of nest success were: Clutch size = 194.29; Size-adjusted nestling mass = 284.48; Daily nest survival rate in 2011 = 153.90; Daily nest survival rate in 2012 = 102.38; Number of fledglings = 147.71.

TABLE 5.

Best-supported models (ΔAIC_c < 2.00) of McCown's Longspur nest success within wind farms in southeastern Wyoming, 2011–2012. Shown are models with the number of parameters (K) and their Akaike model weight (w_i). The AIC_c value of the top model for each nest success metric were: Clutch size = 94.72; Size-adjusted nestling mass = 148.52; Daily nest survival rate = 125.12; Number of fledglings = 61.51.

Patterns of Horned Lark clutch size and number of fledglings were not related to any development, nest-site habitat, or neighborhood habitat characteristics. Horned Lark size-adjusted nestling mass was weakly negatively related to turbine density within a 5 km radius of the nest (β = −0.02; 95% CI: −0.038, −0.002; Figure 1). The top-ranked model for nest survival of Horned Lark nests within each model set (development, nest-site habitat, and neighborhood habitat) was consistent in both 2011 and 2012 turbine density within 2 km of the nest, nest-site vegetation height, and distance to nearest shrubby edge. However, the ranking and predictive power in the final model set that combined these variables differed between years. In 2011, Horned Lark daily nest survival was negatively related to turbine density within a 2 km radius (β = −0.06; 95% CI: −0.12, < −0.00; Figure 2). The probability of a nest surviving the entire nesting period (∼20 days) ranged from 0.74 at turbine density of 10 to 0.21 at turbine density of 39. In 2012, however, turbine density within a 2 km radius (8 to 28 turbines in the areas surveyed) alone was not predictive of nest survival (β = −0.06; 95% CI: −0.16, 0.04). Instead, the highest ranked model of nest survival was the additive model of turbine density within 2 km, vegetation height, and distance to shrub edge. In this additive model, the confidence intervals of the slopes crossed zero for the turbine density and distance to shrub edge predictors, but vegetation height was positively related to nest survival when the other terms were present (β = 0.27; 95% CI: 0.01, 0.53).

FIGURE 1.

Horned Lark size-adjusted nestling mass in relation to the density of turbines within a 5 km radius of the nest on wind farms in southeastern Wyoming, 2011–2012. Points represent nestlings and the dashed line represents the predicted relationship based on a general linear mixed model with turbine density as the fixed effect and nest as a random effect to account for relatedness of nestlings within a given nest. The average size-adjusted mass for a given size is scaled to 0, so nestlings represented by points >0 were heavy for their size, and those <0 were light given their size.

FIGURE 2.

The probability of daily survival of Horned Lark nests on wind farms in southeastern Wyoming in 2011 decreased with wind turbine density within a 2 km radius, as modeled using nest survival models in RMark. Dashed lines represent 95% confidence intervals.

McCown's Longspur clutch size, size-adjusted nestling mass, and number of fledglings were not described well by our development, nest-site habitat, or neighborhood habitat models, with 95% CIs of the slopes of all top-ranked models crossing zero and low R² values (<20%). McCown's Longspur nest survival rates were best predicted by an additive model of turbine density within 1 km, vegetation density, and grassland area. The 95% CIs of the slope estimates of turbine density and grassland area both crossed zero, whereas vegetation density was negatively related to daily nest survival when the other terms were considered (β = −1.02; 95% CI: −1.90, −0.14). The univariate model of vegetation density at 10–20 cm height was also well supported, with a similar weakly negative pattern of daily nest survival with increasing vegetation density (β = −0.83; 95% CI: −1.64, −0.01).