Diurnal Temperature and Time Affect Visitation Patterns of Honey Bees
DOI:
https://doi.org/10.13102/sociobiology.v72i1.11384Keywords:
visitation rate, Day time, diurnal temperature, Apis cerana, daily patternAbstract
Temperature is one of the most important environmental factors affecting honey bee activity, while ambient temperature varies widely during the daytime. We speculated that the daily visitation patterns of honey bees were closely related to the time of day and temperature. Our understanding of the effects of ambient temperature and daytime on visitation patterns of honey bees is limited. Here, we surveyed the visitation rate of honey bees (both Apis cerana and Apis mellifera) to flowers of 14 cultivated species and compared the visitation patterns of honey bees concerning diurnal temperature and time. Our observations suggested that diurnal temperature variation was significantly positively correlated with the visitation rate of honey bees only in three plant species. Honey bees began visiting flowers when the ambient temperature exceeded 16 °C. The optimal temperature range for foraging of honey bees was 38-42 °C. The maximum average temperature occurred between 1300-1400 h, while the optimal visitation time for honey bees was 1400-1500 h, which did not correspond to the maximum average temperature. Our results suggested that the visitation patterns of honey bees were affected by both the time of day and temperature. Honey bees tended to visit more flowers in the noon and afternoon when the temperature was higher than in the forenoon.
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References
Abou-Shaara, H.F. (2014). The foraging behaviour of honey bees, Apis mellifera: a review. Veterinarni Medicina, 59: 1-10.
Abou-Shaara, H.F., Owayss, A.A., Ibrahim, Y.Y. & Basuny, N.K. (2017). A review of impacts of temperature and relative humidity on various activities of honey bees. Insectes Sociaux, 64: 455-463.
Aizen, M.A. & Harder, L.D. (2009). The global stock of domesticated honey bees is growing slower than agricultural demand for pollination. Current Biology, 19: 915-918.
Arroyo, M.T.K., Armesto, J.J. & Primack, R.B. (1985). Community studies in pollination ecology in the high temperate Andes of Central Chile. II. Effect of temperature on visitation rates and pollination possibilities. Plant Systematics and Evolution, 149: 187-203.
Bennett, M.F. & Renner, M. (1963). The collecting performance of honey bees under laboratory conditions. Biological Bulletin, 125: 416-430.
Burrill, R.M. & Dietz, A. (1981). The response of honey bees to variations in solar radiation and temperature. Apidologie, 12: 319-328.
Corbet, S.A. & Huang, S-Q. (2016). Small bees overheat in sunlit flowers: do they make cooling flights? Ecological Entomology, 41: 344-350.
Corbet, S.A., Fussell, M., Ake, R., Fraser, A., Gunson, C., Savage, A. & Smith, K. (1993). Temperature and the pollinating activity of social bees. Ecological Entomology, 18: 17-30.
Cui, Q. & Corlett, R.T. (2016). Seasonal and diurnal patterns of activity in honey bees (Apis spp.) on the northern edge of the Asian tropics; their implications for the climate-change resilience of pollination. Tropical Conservation Science, 9: 1-9.
Fox, J. & Weisberg, S. (2011). An R companion to applied regression. Thousand Oaks, CA: Sage Publications.
Glass, J.R. & Harrison, J.F. (2024). A thermal performance curve perspective explains decades of disagreements over how air temperature affects the flight metabolism of honey bees. Journal of Experimental Biology, 227: 246926.
Heinrich, B. (1979). Keeping a cool head: honey bee thermo-regulation. Science, 205: 1269-1271.
Herrera, C.M. (1990). Daily patterns of pollinator activity, differential pollinating effectiveness, and floral resource availability, in a summer-flowering Mediterranean shrub. Oikos, 58: 277-288.
Kuznetsova, A., Brockhoff, P.B. & Christensen, R.H. B. (2017). lmer Test Package: tests in linear mixed effects models. Journal of Statistical Software, 82: 1-26.
Lehmann, M., Gustav, D. & Galizia, C. G. (2011). The early bee catches the flower-circadian rhythmicity 5 influences learning performance in honey bees, Apis mellifera. Behavioral Ecology and Sociobiology, 65: 205-215.
Lenth, R., Singmann, H., Love, J., Buerkner, P. & Herve, M. (2020). Emmeans: estimated marginal means, aka least-squares means. R package ver. 1.5.1. https://cran.r-project. org/package=emmeans (28 June 2021).
Moore, D. & Rankin, M.A. (1983). Diurnal changes in the accuracy of the honey bee foraging rhythm. Biological Bulletin, 164: 471-482.
Nishanthini, K. & Kanagarajan, R. (2024). Temporal and spatial foraging activity of Indian honey bee (Apis cerana indica F.) at different migratory sites. Sociobiology, 71: e9733.
Owayss, A.A., Shebl, M.A., Iqbal, J., Awad, A.M., Raweh, H.S. & Alqarni, A.S. (2020). Phacelia tanacetifolia can enhance conservation of honey bees and wild bees in the drastic hot-arid subtropical Central Arabia. Journal of Apicultural Research, 59: 569-582.
Potts, S.G., Roberts, S.P.M., Dean, R., Marris, G., Brown, M.A., Jones, R., Neumann, P. & Settele, J. (2010). Declines of managed honey bees and beekeepers in Europe. Journal of Apicultural Research, 49: 15-22.
Su, R., Dai, W., Yang, Y., Wang, X., Gao, R., He, M., Zhao, C. & Mu, J. (2022). Introduced honey bees increase host plant abundance but decrease native bumble bee species richness and abundance. Ecosphere, 13: e4085.
Tan, K., Yang, S., Wang, Z., Radloff, S. E., & Oldroyd, B. P. (2012). Differences in foraging and broodnest temperature in the honey bees Apis cerana and A. mellifera. Apidologie, 43: 618-623.
Thrasyvoulou, A. & Basilis, T. (1998). Observation of Phacelia tanacetifolia as a food plant for honey bees and other insects. Entomologia Hellenica, 12: 47-53.
Willmer, P. (2011). Pollination and floral ecology. Princeton: Princeton University Press.
Young, A.M., Kodabalagi, S., Brockmann, A. & Dyer, F.C. (2021). A hard day’s night: Patterns in the diurnal and nocturnal foraging behavior of Apis dorsata across lunar cycles and seasons. PLoS One, 16: e0258604.
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Copyright (c) 2025 Deng-Fei Li, Ju Tang, Xiao-Dong Fan, Yi-Dan Chen, Zhen Liu, Ai-Ting Liang, Yi-Tao He, Xian-Chun Yan

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