Forecasting bark beetle early flight activity with plant phenology

C Zang,R Helm,A Menzel,Th Sparks

doi:10.3354/cr01346

Abstract

Bark beetle outbreaks are a major threat to forest productivity, and a robust forecast of early flight activity is necessary for inhibition or mitigation of large-scale infestations. We used spring phenology of common wild plants in a phenology-based forecasting approach for European spruce bark beetle Ips typographicus L. early flight activity in Bavaria, Southern Germany, and tested this novel approach against traditional thermal sum-based predictions. Our phenology- based forecast employing the 2 phenological phases of first flowering of common snowdrop Galanthus nivalis L. and leaf budburst of horse chestnut Aesculus hippocastanum L. proved to be more robust and accurate than the thermal sum-based forecast. This is explained by both bark beetle phenology and plant phenology being results of a complex control chain of environmental factors, which can be approximated by temperature sums only to a limited degree. However, our space-for-time approach demonstrates strong and unequivocal temperature sensitivity of bark beetle and plant phenology. This indicates a common pattern in bioclimatic mediation of ecophys- iological processes for both plants and insects as the mechanistic foundation for forecasting. In the case of costly bark beetle activity monitoring data often characterised by gaps and irregular sam- pling intervals, plant phenology can thus provide an easily observable alternative or complemen- tary predictor for early flight activity. Our results indicate that forest practitioners can benefit from simple phenological observations to improve the timing of adequate management measures to mitigate bark beetle mass infestations.

Highlights

It is estimated that 3 million m3 of wood were damaged by bark beetles annually between 1950 and 2000 in Europe (Schelhaas et al 2003)
Zang et al.: Forecasting bark beetle flight activity with plant phenology approach within a Monte-Carlo resampling scheme, we show that predictions based on 2 spring phenophases, viz. first flowering of common snowdrop Galanthus nivalis L. and leaf budburst of horse chestnut Aesculus hippocastanum L., generate more precise and robust forecasts of bark beetle early flight activity than a traditional thermal sum-based approach
We used trap count data from a large area of distributed forest sites across Bavaria, which is unique compared to previously published studies on the phenology of bark beetles

Summary

Introduction

It is estimated that 3 million m3 of wood were damaged by bark beetles annually between 1950 and 2000 in Europe (Schelhaas et al 2003). The high financial penalties resulting from the inevitable sanitary fellings have encouraged infestation research to address the future consequences of changed pest pressure as well as to establish efficient monitoring schemes for bark beetles. The European spruce bark beetle Ips typographus L. is one of the major tree-killing bark beetles in Eurasia (Öhrn et al 2014). The adults hibernate in forest litter and host trees. Under favourable conditions in spring, they search for vulnerable host trees, aggregate by pheromones, burrow through the weakened bark, mate and lay eggs in tunnels built in the inner bark and phloem. One (Northern Europe) to two generations (Central Europe) are common, and in Publisher: Inter-Research · www.int-res.com

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Conclusion