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This title compares and contrasts the unique traits of the pileated woodpecker (a zebra-striped head and a vibrant red crest) to other insect-hunting birds.

Most examples of woodpeckers preying on vertebrates are thought to be opportunistic, and the wider role that some woodpeckers play as nest predators of other birds has not been appreciated until recently. To date. predation on nestling birds has been documented in at least 10 woodpecker species, including 5 of the 6 species of Melanerpes that nest in the United States. From 2018 to 2020. we documented 57 instances in which adult Lewis's Woodpeckers (Melanerpes lewis) provisioned young with nestling passerines (11.9% of 480 food deliveries), which constitutes the first verification of nest predation in this species. Among picids, nest predation is considered to be a widespread and typical foraging strategy only in the Redbellied Woodpecker (M. earolinus) and Great Spotted Woodpecker (Dendrocopas major). We suggest that additional research will reveal that other woodpecker species routinely prey on nestling birds. Received 12 December 2020. Accepted 22 February- 2021.

Documenting biodiversity and wildlife behavior is time-consuming and potentially invasive. Remotely placed cameras often are used to increase sampling and minimize disturbance of focal animals. Such wildlife monitoring programs can entail numerous and lengthy videos requiring massive amounts of time to analyze their content. We evaluated the efficacy of a computer program, MotionMeerkat (http://benweinstein.weebly.com/motionmeerkat.html), for automated detection of motion in 21 continuous, 3-hour-long videos monitoring woodpecker (Picidae) nest cavities during 2016 in Washington, USA. The program produces still-image frame captures from the video where motion was detected, files logging the video time-stamps of each frame, and x,y coordinates within each frame where motion was detected. We compared program results with video reviews conducted by students using a standard protocol for identifying movement events and species identification. The program tagged 60% more motion events of all types, and 38% more motion events of target species (woodpeckers and potential predators), than were found by student reviews. We also conducted sensitivity analyses of the program by varying program input settings; results suggest that optimal settings depend on the video quality, environmental conditions, desired target species, and type of motion. We conclude that automated motion-detection programs such as MotionMeerkat can play important roles in use of continuous videos for wildlife monitoring, but results need to be reviewed by the researcher.

Explaining the mechanism of the coexistence of sympatric species is an important goal of ecology. Five species of woodpeckers coexist in the broadleaved Korean pine forest of Liangshui National Nature Reserve, including the Black Woodpecker (Dryocopus martius), Great Spotted Woodpecker (Dendrocopos major), Lesser Spotted Woodpecker (Dendrocopos minor), Three-toed Woodpecker (Picoides tridactylus), and White-backed Woodpecker (Dendrocopos leucotos). Woodpeckers are considered to be keystone species because of their role as ecosystem engineers, creating breeding and shelter sites for many vertebrate and invertebrate taxa. As woodpeckers are predominant in primary forests, they are sensitive to changes in forest ecosystems. To understand their coexistence mechanisms and propose conservation strategies, it is necessary to investigate their foraging niche differentiation. This study aimed to identify the foraging behavior parameters and foraging tree parameters of five woodpecker species in Liangshui Reserve from October to December. The foraging niches of five woodpecker species were observed, including the type of foraging techniques, foraging height, foraging site, foraging duration, tree species being foraged upon, diameter of the foraging tree at breast height, foraging tree height, and decay status of trees. Our results identified that there were significant differences in the overall foraging ecology of the five species of woodpecker at Liangshui Reserve. The Great Spotted Woodpecker and Lesser Spotted Woodpecker had more diverse foraging patterns and preferred to forage on live trees. The Black Woodpecker and Three-toed Woodpecker excavated and pecked at the trunks of decaying spruce and fir trees. The White-backed Woodpecker preferred to forage in broadleaved trees. The choice of foraging sites was complicated. The size of the foraging trees and decay status of trees were important bases for woodpeckers when choosing trees to forage from. Different woodpeckers achieve stable coexistence through the separation of their foraging niches. This information regarding foraging behavior and foraging tree characteristics provides a basis to study the coexistence patterns of woodpeckers. Our research into woodpecker foraging should be used to inform forest management practices, protect forest ecosystem diversities, and maintain woodpecker community diversity.

Variation in fire characteristics, termed pyrodiversity, plays an important role in structuring post‐fire communities, but little is known about the importance of pyrodiversity for individual species. The availability of diverse post‐fire habitats may be key for fire‐associated species if they require different resources at different life‐history stages. We tested for age‐specific habitat relationships in the black‐backed woodpecker, a post‐fire specialist. We used radio‐telemetry to track fledgling and adult woodpeckers in burned forests and built resource selection functions to compare the effect of stand‐, tree‐ and snag‐level covariates between adults and fledglings. Fledgling black‐backed woodpeckers selected habitat with more live trees than adults and used more heterogeneous habitats burned at lower severity, illustrating strong age‐dependent effects on habitat selection. Within selected stands, fledglings were less likely to use snags and more likely to use live trees when compared to adults, but both age classes showed strong positive selection for larger‐diameter trees (live and dead). Over the 60 days after leaving their nests, fledglings showed an increasing propensity to use snags rather than live trees. Our results provide evidence that the predation–starvation hypothesis, which posits a trade‐off between foraging efficiency and the need to minimise predation risk, plays a role in structuring the age‐dependent habitat use of a burned forest specialist. Adult black‐backed woodpeckers selected resources associated with food availability, but these resources occurred in relatively open, exposed habitat. Fledglings selected habitat that provided increased cover, perhaps as a strategy to reduce predation risk. Synthesis and applications. Globally, fires are increasing in severity and extent, leading to increased focus on fire‐associated species that play keystone roles in facilitating biodiversity resilience. Our findings suggest that a diversity of patches burned at different severities may benefit post‐fire specialists like the black‐backed woodpecker at multiple life‐history stages. The increasing prevalence of large, homogeneously high‐severity ‘megafires’ may present an emerging threat even to post‐fire specialists, and we urge land managers to consider opportunities to promote pyrodiversity in the face of novel fire regimes. Globally, fires are increasing in severity and extent, leading to increased focus on fire‐associated species that play keystone roles in facilitating biodiversity resilience. Our findings suggest that a diversity of patches burned at different severities may benefit post‐fire specialists like the black‐backed woodpecker at multiple life‐history stages. The increasing prevalence of large, homogeneously high‐severity ‘megafires’ may present an emerging threat even to post‐fire specialists, and we urge land managers to consider opportunities to promote pyrodiversity in the face of novel fire regimes.

1. Fire creates challenges and opportunities for wildlife through rapid destruction, modification and creation of habitat. Fire has spatially variable effects on landscapes; however, for species that benefit from the ephemeral resource patches created by fire, it is critical to understand characteristics of fires that promote postfire colonization and persistence and the spatial scales on which they operate. 2. Using a model postfire specialist, the black-backed woodpecker (Picoides arcticus), we examined how colonization and persistence varied across two spatial scales as a function of four characteristics of fire regimes—fire severity, fire size, fire ignition date and number of years since fire. 3. We modelled black-backed woodpecker colonization and persistence using data from 108 recently burned forests in the Sierra Nevada and southern Cascades ecoregions of California, USA, that we monitored for up to 10 years following fire. We employed a novel, spatially hierarchical, dynamic occupancy framework which differentiates colonization and persistence at two spatial scales: across fires and within fires. 4. We found strong effects of fire characteristics on dynamic rates, with colonization and persistence declining across both spatial scales with increasing years since fire. Additionally, at sites within fires, colonization decreased with fire size and increased with fire severity and for fires with later ignition dates. 5. Our results support the notion that different aspects of a species' environment are important for population processes at different spatial scales. As habitat quality is ephemeral for any given postfire area, our results illustrate the importance of time since fire in structuring occupancy at the fire level, with other characteristics of fires playing larger roles in determining abundance within individual fires. Our results contribute to the broader understanding of how variation in fire characteristics influences the colonization and persistence of species using ephemeral habitats, which is necessary for conserving and promoting postfire biodiversity in the context of rapidly shifting fire regimes.

Woodpeckers and other primary cavity excavators (PCEs) are important worldwide for excavating cavities in trees, and a large number of studies have examined their nesting preferences. However, quantitative measures of wood hardness have been omitted from most studies, and ecologists have focused on the effects of external tree- and habitat-level features on nesting. Moreover, information is lacking on the role of wood hardness in limiting nesting opportunities for this important guild. Here, we used an information theoretic approach to examine the role of wood hardness in multi-scale nest site selection and in limiting nesting opportunities for six species of North American PCEs. We found that interior wood hardness at nests ( n = 259) differed from that at random sites, and all six species of PCE had nests with significantly softer interior wood than random trees ( F 1, 517 = 106.15, P < 0.0001). Accordingly, interior wood hardness was the most influential factor in our models of nest site selection at both spatial scales that we examined: in the selection of trees within territories and in the selection of nest locations on trees. Moreover, regardless of hypothesized excavation abilities, all the species in our study appeared constrained by interior wood hardness, and only 4-14% of random sites were actually suitable for nesting. Our findings suggest that past studies that did not measure wood hardness counted many sites as available to PCEs when they were actually unsuitable, potentially biasing results. Moreover, by not accounting for nest site limitations in PCEs, managers may overestimate the amount of suitable habitat. We therefore urge ecologists to incorporate quantitative measures of wood hardness into PCE nest site selection studies, and to consider the limitations faced by avian cavity excavators in forest management decisions.