12 research outputs found
Beyond climate envelopes: effects of weather on regional population trends in butterflies
Although the effects of climate change on biodiversity are increasingly evident by the shifts in species ranges across taxonomical groups, the underlying mechanisms affecting individual species are still poorly understood. The power of climate envelopes to predict future ranges has been seriously questioned in recent studies. Amongst others, an improved understanding of the effects of current weather on population trends is required. We analysed the relation between butterfly abundance and the weather experienced during the life cycle for successive years using data collected within the framework of the Dutch Butterfly Monitoring Scheme for 40 species over a 15-year period and corresponding climate data. Both average and extreme temperature and precipitation events were identified, and multiple regression was applied to explain annual changes in population indices. Significant weather effects were obtained for 39 species, with the most frequent effects associated with temperature. However, positive density-dependence suggested climatic independent trends in at least 12 species. Validation of the short-term predictions revealed a good potential for climate-based predictions of population trends in 20 species. Nevertheless, data from the warm and dry year of 2003 indicate that negative effects of climatic extremes are generally underestimated for habitat specialists in drought-susceptible habitats, whereas generalists remain unaffected. Further climatic warming is expected to influence the trends of 13 species, leading to an improvement for nine species, but a continued decline in the majority of species. Expectations from climate envelope models overestimate the positive effects of climate change in northwestern Europe. Our results underline the challenge to include population trends in predicting range shifts in response to climate change
COMMENTARY: Overstretching attribution
The biological world is responding rapidly to a changing climate, but attempts to attribute individual impacts to rising greenhouse gases are ill-advised
Effect of local weather on butterfly flight behaviour, movement, and colonization: significance for dispersal under climate change
Recent climate change is recognized as a main cause of shifts in geographical
distributions of species. The impacts of climate change may be aggravated by habitat
fragmentation, causing regional or large scale extinctions. However, we propose that climate
change also may diminish the effects of fragmentation by enhancing flight behaviour
and dispersal of ectothermic species like butterflies. We show that under weather conditions
associated with anticipated climate change, behavioural components of dispersal of
butterflies are enhanced, and colonization frequencies increase. In a field study, we
recorded flight behaviour and mobility of four butterfly species: two habitat generalists
(Coenonympha pamphilus; Maniola jurtina) and two specialists (Melitaea athalia;
Plebejus argus), under different weather conditions. Flying bout duration generally
increased with temperature and decreased with cloudiness. Proportion of time spent flying
decreased with cloudiness. Net displacement generally increased with temperature. When
butterflies fly longer, start flying more readily and fly over longer distances, we expect
dispersal propensity to increase. Monitoring data showed that colonization frequencies
moreover increased with temperature and radiation and decreased with cloudiness.
Increased dispersal propensity at local scale might therefore lower the impact of habitat
fragmentation on the distribution at a regional scale. Synergetic effects of climate change
and habitat fragmentation on population dynamics and species distributions might therefore
appear to be more complex than previously assumed.