Abstract
Atmospheric conditions fundamentally influence the timing, intensity, energetics, and geography of avian migration. While radar is typically used to infer the influence of weather on the magnitude and spatiotemporal patterns of nocturnal bird migration, monitoring the flight calls produced by many bird species during nocturnal migration represents an alternative methodology and provides information regarding the species composition of nocturnal migration. We used nocturnal flight call (NFC) recordings of at least 22 migratory songbirds (14 warbler and 8 sparrow species) during fall migration from eight sites along the mainland and island coasts of Rhode Island to evaluate five hypotheses regarding NFC detections. Patterns of warbler and sparrow NFC detections largely supported our expectations in that (1) NFC detections associated positively and strongly with wind conditions that influence the intensity of coastal bird migration and negatively with regional precipitation; (2) NFCs increased during conditions with reduced visibility (e.g., high cloud cover); (3) NFCs decreased with higher wind speeds, presumably due mostly to increased ambient noise; and (4) coastal mainland sites recorded five to nine times more NFCs, on average, than coastal nearshore or offshore island sites. However, we found little evidence that (5) nightly or intra-night patterns of NFCs reflected the well-documented latitudinal patterns of migrant abundance on an offshore island. Despite some potential complications in inferring migration intensity and species composition from NFC data, the acoustic monitoring of NFCs provides a viable and complementary methodology for exploring the spatiotemporal patterns of songbird migration as well as evaluating the atmospheric conditions that shape these patterns.
Highlights
Atmospheric dynamics fundamentally influence the timing, intensity, energetics, and geography of avian migration [1,2,3]
We evaluated five hypotheses regarding the detection of migrant songbird nocturnal flight call (NFC) along the Atlantic Coast of southern New England in relation to atmospheric and ambient conditions, as well as coastal context: (1) NFC detections vary strongly with the atmospheric conditions that influence the intensity of bird migration in general and coastal migration in particular; (2) NFC detections increase under conditions expected to hinder visual communication; (3) NFC detections decrease in association with weather conditions that increase ambient noise, high winds, as well as other non-wind sources of ambient noise
NFC detections peaked in late September/early October or mid-October and declined through the end of the season (Figure 3), regardless of site, the data did not justify a curvilinear fit for a few sites (i.e., Figure 3D, F, G)
Summary
Atmospheric dynamics fundamentally influence the timing, intensity, energetics, and geography of avian migration [1,2,3]. The increased densities of migrants at stopover sites along these ‘leading lines’ [10] can reduce energy replenishment rates via competition as well as increase the risk of predation [11,12,13,14]. These potential densitydependent consequences substantiate the need to identify the environmental factors that direct the movements and distribution of songbirds during migration, along ecological barriers that may experience disproportionately high migrant densities
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