Abstract
Simple SummaryBats often fly near wind turbines. The fatalities associated with this behavior continue to be an issue for wind energy development and wildlife conservation. We tested an experimental method intended to reduce bat fatalities at the wind turbines. We assumed that bats navigate over long distances at night by dim-light vision and might be dissuaded from approaching artificially lit structures. For over a year, we experimentally lit wind turbines at night with dim, flickering ultraviolet (UV) light while measuring the presence and activity of bats, birds, and insects with thermal-imaging cameras. We detected no statistical differences in the activity of the bats, insects, or birds at a test turbine when lit with UV light compared with that of unlit nights. Additional experiments to test this or other possible bat-deterrence methods may benefit from considering subtle measures of animal response that can provide useful information on the possible behavioral effects of fatality-reduction experiments.Wind energy producers need deployable devices for wind turbines that prevent bat fatalities. Based on the speculation that bats approach turbines after visually mistaking them for trees, we tested a potential light-based deterrence method. It is likely that the affected bats see ultraviolet (UV) light at low intensities. Here, we present the results of a multi-month experiment to cast dim, flickering UV light across wind turbine surfaces at night. Our objectives were to refine and test a practical system for dimly UV-illuminating turbines while testing whether the experimental UV treatment influenced the activity of bats, birds, and insects. We mounted upward-facing UV light arrays on turbines and used thermal-imaging cameras to quantify the presence and activity of night-flying animals. The results demonstrated that the turbines can be lit to the highest reaches of the blades with “invisible” UV light, and the animal responses to such experimental treatment can be concurrently monitored. The UV treatment did not significantly change nighttime bat, insect, or bird activity at the wind turbine. Our findings show how observing flying animals with thermal cameras at night can help test emerging technologies intended to variably affect their behaviors around wind turbines.
Highlights
Prior to the late 1990s, bat fatalities resulting from collisions with human-made structures were uncommon [1]
At least 5 species of 4 bat genera are known to occur at the site, including the big brown bat (Eptesicus fuscus), the fringed myotis (Myotis thysanodes), the silver-haired bat (Lasionycteris noctivagans), the hoary bat (Lasiurus cinereus), and the eastern red bat (Lasiurus borealis), as well as other species of Myotis that could not be reliably classified by their echolocation calls [64]
The UV illumination was invisible to humans; yet, we confirmed that the turbine surfaces were lit to the highest reaches of the blades (Figure 5)
Summary
Prior to the late 1990s, bat fatalities resulting from collisions with human-made structures were uncommon [1]. Reports of bat collision fatalities continue to accumulate from wind energy facilities all over the world and contribute to wind turbines ranking highest among the currently known sources of mass mortality in bats [5,6,7,8,9,10]. This bat/turbine problem disproportionately affects certain species, potentially threatening their populations at scales ranging from entire continents to remote islands (e.g., the North American hoary bat [Lasiurus cinereus] and the Hawaiian hoary bat [L. semotus] [8,11]). Widespread bat fatalities impede wind energy operations, and we lack proven methods for preventing the fatalities that are free of other environmental, economic, or energy availability effects
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