Abstract
Red‐naped sapsuckers (Sphyrapicus nuchalis) are functionally important because they create sapwells and cavities that other species use for food and nesting. Red‐naped sapsucker ecology within aspen (Populus tremuloides) has been well studied, but relatively little is known about red‐naped sapsuckers in conifer forests. We used light detection and ranging (LiDAR) data to examine occupancy patterns of red‐naped sapsuckers in a conifer‐dominated system. We surveyed for sapsuckers at 162 sites in northern Idaho, USA, during 2009 and 2010. We used occupancy models and an information‐theoretic approach to model sapsucker occupancy as a function of four LiDAR‐based metrics that characterized vegetation structure and tree harvest, and one non‐LiDAR metric that characterized distance to major roads. We evaluated model support across a range of territory sizes using Akaike's information criterion. Top model support was highest at the 4‐ha extent, which suggested that 4 ha was the most relevant scale describing sapsucker occupancy. Sapsuckers were positively associated with variation of canopy height and harvested area, and negatively associated with shrub and large tree density. These results suggest that harvest regimes and structural diversity of vegetation at moderate extents (e.g., 4 ha) largely influence occurrence of red‐naped sapsuckers in conifer forests. Given the current and projected declines of aspen populations, it will be increasingly important to assess habitat relationships, as well as demographic characteristics, of aspen‐associated species such as red‐naped sapsuckers within conifer‐dominated systems to meet future management and conservation goals.
Highlights
Understanding factors that influence the distribution and occupancy of functionally important species is critical for ecosystem conservation and management
Ecosystem engineers are functionally important within ecological communities (Daily et al 1993; Jones et al 1994; Robles and Martin 2013), and understanding factors that influence their occupancy is essential to understanding the ecological integrity of a site
Using light detection and ranging (LiDAR) data, we characterized how vegetation structure and disturbance influence the occupancy of the red-naped sapsucker, an ecosystem engineer, in northern Idaho
Summary
Understanding factors that influence the distribution and occupancy of functionally important species is critical for ecosystem conservation and management. Ecosystem engineers are animals that directly or indirectly influence resources available to other species (Jones et al 1994, 1997, 2010). Through their physical alteration of habitat, ecosystem engineers can form keystone structures (Tews et al 2004; Remm and Lo~hmus 2011), which are ecological features that increase biological diversity (e.g., beaver dams, animal burrows, woodpecker cavities). Excavated cavities are important nesting habitats for a variety of vertebrate species including birds, mammals, amphibians, and reptiles (McComb and Noble 1981; Martin et al 2004; Robles and Martin 2013), as well as myriad arthropods and fungi (Jackson and Jackson 2004; Tomas et al 2008; Cockle et al 2012)
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