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Modeling pollinating bee visitation rates in heterogeneous landscapes from foraging theory

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  • Olsson, Ola
  • Bolin, Arvid
  • Smith, Henrik G.
  • Lonsdorf, Eric V.

Abstract

Pollination by bees is important for food production. Recent concerns about the declines of both domestic and wild bees, calls for measures to promote wild pollinator populations in farmland. However, to be able to efficiently promote and prioritize between measures that benefit pollinators, such as modified land use, agri-environment schemes, or specific conservation measures, it is important to have a tool that accurately predicts how bees use landscapes and respond to such measures. In this paper we compare an existing model for predicting pollination (the “Lonsdorf model”), with an extension of a general model for habitat use of central place foragers (the “CPF model”). The Lonsdorf model has been shown to perform relatively well in simple landscapes, but not in complex landscapes. We hypothesized that this was because it lacks a behavioral component, assuming instead that bees in essence diffuse out from the nest into the landscape. By adding a behavioral component, the CPF model in contrast assumes that bees only use those parts of the landscape that enhances their fitness, completely avoiding foraging in other parts of the landscape. Because foraging is directed toward the most rewarding foraging habitat patches as determined by quality and distance, foraging habitat will include a wide range of forage qualities close to the nest, but a much narrower range farther away. We generate predictions for both simple and complex hypothetical landscapes, to illustrate the effect of including the behavioral rule, and for real landscapes. In the real landscapes the models give similar predictions for visitation rates in simple landscapes, but more different predictions in heterogeneous landscapes. We also analyze the consequences of introducing hedgerows near a mass-flowering crop field under each model. The Lonsdorf model predicts that any habitat improvement will enhance pollination of the crop. In contrast, the CPF model predicts that the hedgerow must provide good nesting sites, and not just foraging opportunities, for it to benefit pollination of the crop, because good forage quality alone may drain bees away from the field. Our model can be used to optimize pollinator mitigation measures in real landscapes.

Suggested Citation

  • Olsson, Ola & Bolin, Arvid & Smith, Henrik G. & Lonsdorf, Eric V., 2015. "Modeling pollinating bee visitation rates in heterogeneous landscapes from foraging theory," Ecological Modelling, Elsevier, vol. 316(C), pages 133-143.
    • Handle: RePEc:eee:ecomod:v:316:y:2015:i:c:p:133-143
    DOI: 10.1016/j.ecolmodel.2015.08.009
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    References listed on IDEAS

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    1. Olsson, Ola & Brown, Joel S. & Helf, Kurt L., 2008. "A guide to central place effects in foraging," Theoretical Population Biology, Elsevier, vol. 74(1), pages 22-33.
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    Cited by:

    1. Joanne Lee Picknoll & Pieter Poot & Michael Renton, 2021. "A New Approach to Inform Restoration and Management Decisions for Sustainable Apiculture," Sustainability, MDPI, vol. 13(11), pages 1-20, May.
    2. Image, Mike & Gardner, Emma & Breeze, Tom D., 2023. "Co-benefits from tree planting in a typical English agricultural landscape: Comparing the relative effectiveness of hedgerows, agroforestry and woodland creation for improving crop pollination service," Land Use Policy, Elsevier, vol. 125(C).
    3. Stephen B. Stewart & Anthony P. O’Grady & Daniel S. Mendham & Greg S. Smith & Philip J. Smethurst, 2022. "Digital Tools for Quantifying the Natural Capital Benefits of Agroforestry: A Review," Land, MDPI, vol. 11(10), pages 1-32, September.
    4. Baey, Charlotte & Smith, Henrik G. & Rundlöf, Maj & Olsson, Ola & Clough, Yann & Sahlin, Ullrika, 2023. "Calibration of a bumble bee foraging model using Approximate Bayesian Computation," Ecological Modelling, Elsevier, vol. 477(C).
    5. Å owicki, Damian & Fagiewicz, Katarzyna, 2021. "A new model of pollination services potential using a landscape approach: A case study of post-mining area in Poland," Ecosystem Services, Elsevier, vol. 52(C).
    6. Iovanna, R. & Ando, A & Swinton, S. & Kagan, J. & Hellerstein, D. & Mushet, D. & Otto, C., 2017. "Assessing Pollinator Habitat Services to Optimize Conservation Programs," C-FARE Reports 260678, Council on Food, Agricultural, and Resource Economics (C-FARE).
    7. Joseph, Julien & Santibáñez, Fernanda & Laguna, María Fabiana & Abramson, Guillermo & Kuperman, Marcelo N. & Garibaldi, Lucas A., 2020. "A spatially extended model to assess the role of landscape structure on the pollination service of Apis mellifera," Ecological Modelling, Elsevier, vol. 431(C).
    8. Wainger, L. & Ervin, D., 2017. "The Valuation of Ecosystem Services from Farms and Forests Informing a systematic approach to quantifying benefits of conservation programs (Synthesis Chapter)," C-FARE Reports 260677, Council on Food, Agricultural, and Resource Economics (C-FARE).
    9. Carturan, Bruno S. & Siewe, Nourridine & Cobbold, Christina A. & Tyson, Rebecca C., 2023. "Bumble bee pollination and the wildflower/crop trade-off: When do wildflower enhancements improve crop yield?," Ecological Modelling, Elsevier, vol. 484(C).
    10. Bourhis, Yoann & Poggi, Sylvain & Mammeri, Youcef & Le Cointe, Ronan & Cortesero, Anne-Marie & Parisey, Nicolas, 2017. "Foraging as the landscape grip for population dynamics—A mechanistic model applied to crop protection," Ecological Modelling, Elsevier, vol. 354(C), pages 26-36.
    11. Santibañez, Fernanda & Joseph, Julien & Abramson, Guillermo & Kuperman, Marcelo N. & Laguna, María Fabiana & Garibaldi, Lucas A., 2022. "Designing crop pollination services: A spatially explicit agent-based model for real agricultural landscapes," Ecological Modelling, Elsevier, vol. 472(C).

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