My basic research is aimed at understanding the foraging behaviour and population dynamics of natural enemies, particularly parasitoids.
These small insects, often less than 2mm long, have to find their host insects in a very diverse environment in order to be able to feed and reproduce. We study the search and parasitizition behaviour of parasitoids in olfactomers, windtunnels and under natural conditions in the field. We try to find out what kind of information parastitoids use to orient themselves and find their hosts. After having arrived in an area with hosts, we determine in what way and how quickly they localize their hosts. When the parasitoid has contacted the host, we investigate how and when they decide to accept the host for egglaying. If they do not oviposit we try to find out why they reject the host. In addition, population fluctuations of parasitoids and hosts are studied in artificial and natural situations, to see if and how parasitoids are able to regulate numbers of their hosts. Side lines in my research are (1) the anatomy and sensory physiology of parasitoid ovipositors and (2) the discovery of insect parasitism.
My applied research focuses on biological and integrated pest management. One research question is how good natural enemies can quickly be distinguished from useless species. We develop selection criteria which can be applied before field evaluations are done. Part of this study is the design of an individual-based simulation model, in which the effect of changes in the biology of the natural enemy, the pest, the crop and the environment, on the biological control effect can be evaluated. Based on the initial selection with these criteria and the simulation model, natural enemies are then selected and tried out under greenhouse or field conditions. Another research project deals with the risks of importing exotic natural enemies and the design of a protocol for evaluation of exotic species. Finally, we develop criteria for quality control of natural enemies.
Advances in augmentative biological control in IPM
In: Integrated management of insect pests / , Kogan, M., Higley, L.. - London : Taylor & Francis - ISBN 9780429275395 - p. 481 - 507.
Pest kill rate as aggregate evaluation criterion to rank biological control agents: A case study with Neotropical predators of Tuta absoluta on tomato
Bulletin of Entomological Research 109 (2019)6. - ISSN 0007-4853 - p. 812 - 820.
The status of biological control and recommendations for improving uptake for the future
BioControl 63 (2018)1. - ISSN 1386-6141 - p. 155 - 167.
Best practices for the use and exchange of invertebrate biological control genetic resources relevant for food and agriculture
BioControl 63 (2018)1. - ISSN 1386-6141 - p. 149 - 154.
Life history of the Harlequin ladybird, Harmonia axyridis; a global meta-analysis
Do nymphs and adults of three Neotropical zoophytophagous mirids damage leaves and fruits of tomato?
Bulletin of Entomological Research 107 (2017)2. - ISSN 0007-4853 - p. 200 - 207.
Dispersal and interface behaviour of carabid beetles in a landscape mosaic: Field study plus model selection
Het verleden van onze toekomst : kroniek van de Koninklijke Nederlandse Plantenziektekundige Vereniging
Wageningen : KNPV - p.
Reproduction and population parameters of the Nearctic predator Geocoris punctipes at constant and varying temperature regimes
Journal of Applied Entomology 140 (2016)5. - ISSN 0931-2048 - p. 323 - 333.
Life history data and population growth of Tuta absoluta at constant and alternating temperatures on two tomato lines
Bulletin of Insectology 68 (2015)2. - ISSN 1721-8861 - p. 223 - 232.