Bioreplicated coatings for photovoltaic solar panels nearly eliminate light pollution that harms polarotactic insects

Many insect species rely on the polarization properties of object-reflected light for vital tasks like water or host detection. Unfortunately, typical glass-encapsulated photovoltaic modules, which are expected to cover increasingly large surfaces in the coming years, inadvertently attract various s...

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Bibliographic Details
Published in:PloS one 2020-12, Vol.15 (12), p.e0243296
Main Authors: Fritz, Benjamin, Horváth, Gábor, Hünig, Ruben, Pereszlényi, Ádám, Egri, Ádám, Guttmann, Markus, Schneider, Marc, Lemmer, Uli, Kriska, György, Gomard, Guillaume
Format: Article
Language:English
Subjects:
Animals
Aquatic insects
Behavior
Biology and Life Sciences
Conservation
Copying
Diptera
Ecological effects
Ecology
Ecology and Environmental Sciences
Eggs
Engineering and Technology
Entomofauna
Environmental aspects
Ephemeroptera
Field tests
Glass
Harvesting
Horizontal polarization
Influence
Insects
Laboratories
Light
Light pollution
Light sources
Microtexture
Optical properties
Optics
Photovoltaic cells
Photovoltaics
Physical Sciences
Polarimetry
Polarized light
Protection and preservation
Ray tracing
Solar energy
Solar panels
Species
Sunlight
Tabanidae
Topography
Water pollution
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Summary:Many insect species rely on the polarization properties of object-reflected light for vital tasks like water or host detection. Unfortunately, typical glass-encapsulated photovoltaic modules, which are expected to cover increasingly large surfaces in the coming years, inadvertently attract various species of water-seeking aquatic insects by the horizontally polarized light they reflect. Such polarized light pollution can be extremely harmful to the entomofauna if polarotactic aquatic insects are trapped by this attractive light signal and perish before reproduction, or if they lay their eggs in unsuitable locations. Textured photovoltaic cover layers are usually engineered to maximize sunlight-harvesting, without taking into consideration their impact on polarized light pollution. The goal of the present study is therefore to experimentally and computationally assess the influence of the cover layer topography on polarized light pollution. By conducting field experiments with polarotactic horseflies (Diptera: Tabanidae) and a mayfly species (Ephemeroptera: Ephemera danica), we demonstrate that bioreplicated cover layers (here obtained by directly copying the surface microtexture of rose petals) were almost unattractive to these species, which is indicative of reduced polarized light pollution. Relative to a planar cover layer, we find that, for the examined aquatic species, the bioreplicated texture can greatly reduce the numbers of landings. This observation is further analyzed and explained by means of imaging polarimetry and ray-tracing simulations. The results pave the way to novel photovoltaic cover layers, the interface of which can be designed to improve sunlight conversion efficiency while minimizing their detrimental influence on the ecology and conservation of polarotactic aquatic insects.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0243296