Using Thermodynamics to Improve Bat Houses in Cold Climates

Abstract Wildlife managers design artificial structures, such as bird and bat houses, to provide alternative habitats that aid wildlife conservation. However, prototypes may not be equally efficient at all sites due to varying climate or habitat characteristics influencing thermal properties. For example, bat houses are a popular measure employed to protect bats and educate citizens, yet bat houses have achieved limited success in cool climates. To address this problem, we tested different orientations and mountings for both traditional and newly designed bat house models based on modern architectural energy saving concepts, by recording temperatures in bat houses across a climate gradient in Quebec, Canada. Bat houses mounted on buildings had warmer conditions at night than those on poles and warmed sooner in the morning when facing east. Our new insulated model with passive heating maximized the time in the extended optimal temperature range (22 − 40 °C) of targeted species by up to 13% compared to the Classic model, providing bats with an estimated average daily energy savings of up to 7.8% when mounted on a building. We conclude that the use of energy-saving concepts from architecture can improve the thermal performance of wildlife structures.