Tuning the white light spectrum of light emitting diode lamps to reduce attraction of nocturnal arthropods

Longcore, Travis; Aldern, Hannah L.; Eggers, John F.; Flores, Steve; Franco, Lesly; Hirshfield-Yamanishi, Eric; Petrinec, Laina N.; Yan, Wilson A.; Barroso, A.

doi:10.1098/rstb.2014.0125

Cited by 96 publications

(108 citation statements)

References 47 publications

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“…Light intensity was not equal for all street lights, as we compared lighting technologies based on their real‐life application for human needs. However, these differences in intensity are unlikely to have influenced insect attraction as much as spectral differences (Longcore et al., ). Despite both emitting white light, the MH caught approximately five times as many insects as the LED light.…”

Section: Discussionmentioning

confidence: 99%

Quantifying the attractiveness of broad‐spectrum street lights to aerial nocturnal insects

Wakefield

Broyles

Stone

et al. 2017

Journal of Applied Ecology

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Abstract1. Sodium street lights, dominated by long wavelengths of light, are being replaced by broad-spectrum, white lights globally, in particular light-emitting diodes (LEDs).These white lights typically require less energy to operate and are therefore considered "eco-friendly". However, little attention has been paid to the impacts white lights may have upon local wildlife populations.2. We compared insect attraction to orange (high-pressure sodium, HPS) and white (metal halide, MH and LED) street lights experimentally using portable street lights and custom-made flight intercept traps.3. Significantly more (greater than five times as many) insects were attracted to white MH street lights than white (4,250 K) LED and HPS lights. There was no statistical difference in the numbers of insects attracted to LED and HPS lights for most taxa caught. However, rarefaction shows a greater diversity of insects caught at LED than HPS lights. Policy implications.With the current, large-scale conversion to white light-emitting diode (LED) lighting, our results give insight into how changes to street light technology may affect wildlife populations and communities. We recommend avoiding metal halide light installations as they attract many more insects than competing technologies. We highlight the need to tailor LED lighting to prevent disturbances across multiple insect taxa.

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Section: Discussionmentioning

confidence: 99%

Quantifying the attractiveness of broad‐spectrum street lights to aerial nocturnal insects

Wakefield

Broyles

Stone

et al. 2017

Journal of Applied Ecology

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“…With respect to the ALAN itself, the challenges are to determine: (i) the form of dose (intensity)-response relationships for a range of biological impacts of ALAN-almost exclusively, studies to date have contrasted predominantly two ALAN treatments (ALAN versus no ALAN), preventing determination of thresholds and the overall shapes of dose-response functions; and (ii) the form of spectral-response relationships for a range of biological impacts of ALAN-again, as with dose-response relationships, the state-of-the-art experiments are employing just a few spectral treatments [68,71,73] or typical light sources for outdoor lighting with different colour spectra (see [74,75]). Understanding of both dose-response and spectral-response relationships, and their interaction, will be critical to providing the best advice on how to limit the negative biological impacts of ALAN.…”

Section: Individual Organismsmentioning

confidence: 99%

The biological impacts of artificial light at night: the research challenge

Gaston

Visser

Hölker

2015

Phil. Trans. R. Soc. B

395

278

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“…Most interestingly, humans see a much different nocturnal urban environment than other animals as humans see most lights as the same color, yet birds and insects are likely seeing a myriad of differently colored lights in their environment. Thus, humans have altered the natural nightscape with numerous colors of lights, even though previous research has assumed that within type light sources are the same color (Longcore et al ., ; Van Langevelde et al ., ; Donners et al ., ). All light types varied in overall brightness, however, as eyes adapt to light conditions through various mechanisms (e.g.…”

Section: Discussionmentioning

confidence: 99%

“…Although numerous studies have investigated behavioral responses to different light sources (Langevelde et al ., ; van Grunsven et al ., ; Longcore et al ., ; Spoelstra et al ., ), few studies have investigated varied spectral signatures in the environment, see Davies et al . (); Donners et al .…”

Section: Introductionmentioning

confidence: 99%

Connecting spectral radiometry of anthropogenic light sources to the visual ecology of organisms

2019

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Humans have drastically altered nocturnal environments with electric lighting. Animals depend on natural night light conditions and are now being inundated with artificial lighting. There are numerous artificial light sources that differ in spectral composition that should affect the perception of these light sources and due to differences in animal visual systems, the differences in color perception of these anthropogenic light sources should vary significantly. The ecological and evolutionary ramifications of these perceptual differences of light sources remain understudied. Here, we quantify the radiance of nine different street lights comprised of four different light sources: Metal Halide, Mercury Vapor, Light Emitting Diodes, and High‐Pressure Sodium and model how five animal visual systems will be stimulated by these light sources. We calculated the number of photons that photoreceptors in different visual systems would detect. We selected five visual systems: avian UV/VIS, avian V/VIS, human, wolf and hawk moth. We included non‐visual photoreceptors of vertebrates known for controlling circadian rhythms and other physiological traits. The nine light types stimulated visual systems and the photoreceptors within the visual systems differently. Furthermore, we modelled the chromatic contrast (Just Noticeable Differences [JNDs]) and color space overlap for each light type comparison for each visual system to see if organisms would perceive the lights as different colors. The JNDs of most light type comparisons were very high, indicating most visual systems would detect all light types as different colors, however mammalian visual systems would perceive many lights as the same color. We discuss the importance of understanding not only the brightness of artificial light types, but also the spectral composition of light types, as most organisms have different visual systems from humans. Thus, for researchers to understand how artificial light sources affect the visual environment of specific organisms and thus mitigate the effects, spectral information is crucial.

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Tuning the white light spectrum of light emitting diode lamps to reduce attraction of nocturnal arthropods

Cited by 96 publications

References 47 publications

Quantifying the attractiveness of broad‐spectrum street lights to aerial nocturnal insects

Quantifying the attractiveness of broad‐spectrum street lights to aerial nocturnal insects

The biological impacts of artificial light at night: the research challenge

Connecting spectral radiometry of anthropogenic light sources to the visual ecology of organisms

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