首页 | 本学科首页   官方微博 | 高级检索  
     


Avoiding verisimilitude when modelling ecological responses to climate change: the influence of weather conditions on trapping efficiency in European badgers (Meles meles)
Authors:Michael J. Noonan  M. Abidur Rahman  Chris Newman  Christina D. Buesching  David W. Macdonald
Affiliation:1. Wildlife Conservation Research Unit, Department of Zoology, The Recanati‐Kaplan Centre, University of Oxford, Tubney, Abingdon, Oxfordshire, UK;2. WildTeam, Cosmos Center, Malibagh, Dhaka, Bangladesh
Abstract:The signal for climate change effects can be abstruse; consequently, interpretations of evidence must avoid verisimilitude, or else misattribution of causality could compromise policy decisions. Examining climatic effects on wild animal population dynamics requires ability to trap, observe or photograph and to recapture study individuals consistently. In this regard, we use 19 years of data (1994–2012), detailing the life histories on 1179 individual European badgers over 3288 (re‐) trapping events, to test whether trapping efficiency was associated with season, weather variables (both contemporaneous and time lagged), body‐condition index (BCI) and trapping efficiency (TE). PCA factor loadings demonstrated that TE was affected significantly by temperature and precipitation, as well as time lags in these variables. From multi‐model inference, BCI was the principal driver of TE, where badgers in good condition were less likely to be trapped. Our analyses exposed that this was enacted mechanistically via weather variables driving BCI, affecting TE. Notably, the very conditions that militated for poor trapping success have been associated with actual survival and population abundance benefits in badgers. Using these findings to parameterize simulations, projecting best‐/worst‐case scenario weather conditions and BCI resulted in 8.6% ± 4.9 SD difference in seasonal TE, leading to a potential 55.0% population abundance under‐estimation under the worst‐case scenario; 38.6% over‐estimation under the best case. Interestingly, simulations revealed that while any single trapping session might prove misrepresentative of the true population abundance, due to weather effects, prolonging capture–mark–recapture studies under sub‐optimal conditions decreased the accuracy of population estimates significantly. We also use these projection scenarios to explore how weather could impact government‐led trapping of badgers in the UK, in relation to TB management. We conclude that population monitoring must be calibrated against the likelihood that weather conditions could be altering trap success directly, and therefore biasing model design.
Keywords:body‐condition index  capture probability  causality  population estimation  time‐lagged weather
设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号