Papaver rhoeas

Common Poppy

Category: plantae
Primary role: weed
Class: Magnoliopsida
Order: Ranunculales
Family: Papaveraceae
Genus: Papaver

External: GBIF #2888443

1 AI-consensus-verified claim across 1 interaction category.

Related entities

Top entities sharing the most verified claims with Papaver rhoeas.

Bombus terrestris

Buff Tailed Bumblebee

1 shared claim

pollination 1 claim

This entity is the object of pollination by Bombus terrestris (Buff Tailed Bumblebee) · effect: beneficial

“black pollen was primarily poppy Papaver rhoeas L.”

pollinates ✓ 2/2 AI critics agreed

Goulson D. (2010) · Bumblebees: Behaviour, Ecology, and Conservation (Second Edition) · p. 98 #6492454

Aggregated via GloBI — not independently verified by AgroEco.

flower visitor 3

GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/161387222
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/161408987
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/161687680

herbivory 5

GloBI eats Papaver rhoeas Neff, F., Brändle, M., Ambarli, D., Ammer, C., Bauhus, J., Boch, S., Hölzel, N., Klaus, V. H., Kleinebecker, T., Prati, D., Schall, P., Schäfer, D., Schulze, E. D., Seibold, S., Simons, N. K., Weisser, W. W., Pellissier, L., & Gossner, M. M. (2021). Changes in plant-herbivore network structure and robustness along land-use intensity gradients in grasslands and forests. Science Advances, 7(20), 18. https://doi.org/10.1126/SCIADV.ABF3985/SUPPL_FILE/ABF3985_SM.PDF DOI
GloBI eats Papaver rhoeas Neff, F., Brändle, M., Ambarli, D., Ammer, C., Bauhus, J., Boch, S., Hölzel, N., Klaus, V. H., Kleinebecker, T., Prati, D., Schall, P., Schäfer, D., Schulze, E. D., Seibold, S., Simons, N. K., Weisser, W. W., Pellissier, L., & Gossner, M. M. (2021). Changes in plant-herbivore network structure and robustness along land-use intensity gradients in grasslands and forests. Science Advances, 7(20), 18. https://doi.org/10.1126/SCIADV.ABF3985/SUPPL_FILE/ABF3985_SM.PDF DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/230560246
GloBI eats Papaver rhoeas Ellis, W. N. (2022). Plant Parasites of Europe – leafminers, galls and fungi [Database]. https://bladmineerders.nl/
GloBI eats Papaver rhoeas Ellis, W. N. (2022). Plant Parasites of Europe – leafminers, galls and fungi [Database]. https://bladmineerders.nl/

pathogen pressure 4

GloBI hasHost Papaver rhoeas https://mycoportal.org/portal/collections/individual/index.php?occid=11626609
GloBI hasHost Papaver rhoeas https://mycoportal.org/portal/collections/individual/index.php?occid=14691904
GloBI hasHost Papaver rhoeas https://mycoportal.org/portal/collections/individual/index.php?occid=3613767
GloBI parasiteOf Papaver rhoeas Dennis, R.W.G.. 1995. Fungi of the South East England. Royal Botanic Gardens, Kew

pest pressure 1

GloBI hasHost Papaver rhoeas https://www.inaturalist.org/observations/166836480

pollination 187

GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2664.13658 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas Ollerton, J., Trunschke, J. ., Havens, K. ., Landaverde-González, P. ., Keller, A. ., Gilpin, A.-M. ., Rodrigo Rech, A. ., Baronio, G. J. ., Phillips, B. J., Mackin, C. ., Stanley, D. A., Treanore, E. ., Baker, E. ., Rotheray, E. L., Erickson, E. ., Fornoff, F. ., Brearley, F. Q. ., Ballantyne, G. ., Iossa, G. ., Stone, G. N., Bartomeus, I. ., Stockan, J. A., Leguizamón, J., Prendergast, K. ., Rowley, L., Giovanetti, M., de Oliveira Bueno, R., Wesselingh, R. A., Mallinger, R., Edmondson, S., Howard, S. R., Leonhardt, S. D., Rojas-Nossa, S. V., Brett, M., Joaqui, T., Antoniazzi, R., Burton, V. J., Feng, H.-H., Tian, Z.-X., Xu, Q., Zhang, C., Shi, C.-L., Huang, S.-Q., Cole, L. J., Bendifallah, L., Ellis, E. E., Hegland, S. J., Straffon Díaz, S., Lander, T. A. ., Mayr, A. V., Dawson, R. ., Eeraerts, M. ., Armbruster, W. S. ., Walton, B. ., Adjlane, N. ., Falk, S. ., Mata, L. ., Goncalves Geiger, A. ., Carvell, C. ., Wallace, C. ., Ratto, F. ., Barberis, M. ., Kahane, F. ., Connop, S. ., Stip, A. ., Sigrist, M. R. ., Vereecken, N. J. ., Klein, A.-M., Baldock, K. ., & Arnold, S. E. J. . (2022). Pollinator-flower interactions in gardens during the COVID-19 pandemic lockdown of 2020. Journal of Pollination Ecology, 31, 87–96. https://doi.org/10.26786/1920-7603(2022)695. Accessed at <https://github.com/globalbioticinteractions/ollerton2022/archive/7eb71e8e5026ec08c04a69a09860f8927061a8fd.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/1789428
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/288030757
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/162356651
GloBI visitsFlowersOf Papaver rhoeas @article{Barberis_Bitonto_Costantino_Bianco_Birtele_Bonifacino_Cangelmi_Capò_Chroni_d’Agostino_et al._2025, title={Insect-flower interactions in the Mediterranean area: a Citizen Science dataset collated within the LIFE 4 Pollinators project}, volume={39}, url={https://www.pollinationecology.org/index.php/jpe/article/view/872}, DOI={10.26786/1920-7603(2025)872}, abstractNote={&lt;p&gt;Pollinators play a vital role in most terrestrial ecosystems, supporting wild plant communities and enhancing agricultural yields. However, despite their ecological and economic importance, they have been experiencing an alarming decline over the past decades. The Mediterranean region, known for harboring highly diverse communities of plants and pollinators, is particularly vulnerable due to intense anthropogenic pressures. Furthermore, the ecological roles of many floral visitors remain poorly understood, hindering conservation efforts. In response, in recent years, growing attention has been directed toward the contribution that citizens can give in support of pollinator research. An increasing number of projects have adopted a Citizen Science approach to enable large-scale data collection. The LIFE 4 Pollinators project (LIFE18/GIE/IT/000755) “Involving people to protect wild bees and other pollinators in the Mediterranean” aims to promote the conservation of pollinating insects and entomophilous plants across the Mediterranean region by fostering progressive changes in human practices that threaten wild pollinators. In addition to the implementation of several actions to raise awareness, the project launched a web platform to collect photographic records of flower–insect interaction from the public. The platform is expected to remain active for at least ten years, during which we encourage continuing record submissions by interested bodies. With this data paper we are making the current dataset freely accessible to anyone, committing to periodic online updates.&lt;/p&gt;}, journal={Journal of Pollination Ecology}, author={Barberis, Marta and Bitonto, Fortunato Fulvio and Costantino, Roberto and Bianco, Lorenzo and Birtele, Daniele and Bonifacino, Marco and Cangelmi, Giacomo and Capò, Miquel and Chroni, Athanasia and d’Agostino, Marco and et al.}, year={2025}, month={Nov.}, pages={306–315} }. Accessed at <https://github.com/globalbioticinteractions/life4pollinators/archive/74ddb96b7a611646153cb74d7f3fc58e2290dc52.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/298409445
GloBI pollinates Papaver rhoeas Bertrand, C., Eckerter, P. W., Ammann, L., Entling, M. H., Gobet, E., Herzog, F., Mestre, L., Tinner, W., & Albrecht, M. (2019). Data from: Seasonal shifts and complementary use of pollen sources by two bee, a lacewing and a ladybeetle species in European agricultural landscapes (Version 1, p. 359813 bytes) [Dataset]. Dryad. https://doi.org/10.5061/DRYAD.6836P06 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/297061996
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/79783797
GloBI visitsFlowersOf Papaver rhoeas Russo, Laura; Fitzpatrick, Una; Larkin, Michelle et al. (2022). Database of plant-flower visitor interactions from Ireland [Dataset]. Dryad. https://doi.org/10.5061/dryad.kwh70rz47. Accessed at <https://github.com/globalbioticinteractions/russo2022/archive/1bd53f013d878a3ebfdf1126e2708558973790f6.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/325723939
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/69718331
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI interactsWith Papaver rhoeas Tri-Trophic Thematic Collection Network, 2014 (and updates). Version: 2016-03-08. http://tcn.amnh.org/. National Science Foundation grant(s) EF#1115081, EF#1115103, EF#1115080, EF#1115144, EF#1115191, EF#1115104, EF#1115115
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/214389602
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/164675121
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/295343657
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/283857037
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/226849903
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/5538718
GloBI pollinates Papaver rhoeas doi:10.1007/s00442-022-05151-6 DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/82045131
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/82045131
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/82045131
GloBI pollinates Papaver rhoeas doi:10.1002/ecy.2569 DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/219752351
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/325765509
GloBI pollinates Papaver rhoeas doi:10.1007/s00442-022-05151-6 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/168641381
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/240265736
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2664.13658 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas doi:10.1111/ele.12657 DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/45504123
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/52304441
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/128549745
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2664.13658 DOI
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2435.14160 DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/78374415
GloBI interactsWith Episyrphus balteatus https://www.inaturalist.org/observations/61218426
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/153206112
GloBI pollinates Papaver rhoeas doi:10.1111/ele.12657 DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/259148565
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/163668446
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/254324734
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2435.14160 DOI
GloBI visitsFlowersOf Papaver rhoeas T.J. Wood et al., 2017. An assessment of historical and contemporary diet breadth in polylectic Andrena bee species. Biological Conservation, doi:10.1016/j.biocon.2017.09.009 DOI
GloBI interactsWith Papaver rhoeas Tri-Trophic Thematic Collection Network, 2014 (and updates). Version: 2016-03-08. http://tcn.amnh.org/. National Science Foundation grant(s) EF#1115081, EF#1115103, EF#1115080, EF#1115144, EF#1115191, EF#1115104, EF#1115115
GloBI interactsWith Papaver rhoeas Tri-Trophic Thematic Collection Network, 2014 (and updates). Version: 2016-03-08. http://tcn.amnh.org/. National Science Foundation grant(s) EF#1115081, EF#1115103, EF#1115080, EF#1115144, EF#1115191, EF#1115104, EF#1115115
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI visitsFlowersOf Papaver rhoeas R.E. Walton et al., 2020. Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape.. Biology Letters, 16. doi:10.1098/rsbl.2019.0877 DOI
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI visitsFlowersOf Papaver rhoeas R.E. Walton et al., 2020. Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape.. Biology Letters, 16. doi:10.1098/rsbl.2019.0877 DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas R. N. Nichols et al., 2019. The best wildflowers for wild bees. Journal of Insect Conservation, https://link.springer.com/article/10.1007/s10841-019-00180-8
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/69718331
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas R.F. Comont et al., 2019. Bumblebee Conservation Trust: BeeWalk Annual Report 2020. Bumblebee Conservation Trust, doi:10.15468/xde3qb DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/166836480
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas @article{Barberis_Bitonto_Costantino_Bianco_Birtele_Bonifacino_Cangelmi_Capò_Chroni_d’Agostino_et al._2025, title={Insect-flower interactions in the Mediterranean area: a Citizen Science dataset collated within the LIFE 4 Pollinators project}, volume={39}, url={https://www.pollinationecology.org/index.php/jpe/article/view/872}, DOI={10.26786/1920-7603(2025)872}, abstractNote={&lt;p&gt;Pollinators play a vital role in most terrestrial ecosystems, supporting wild plant communities and enhancing agricultural yields. However, despite their ecological and economic importance, they have been experiencing an alarming decline over the past decades. The Mediterranean region, known for harboring highly diverse communities of plants and pollinators, is particularly vulnerable due to intense anthropogenic pressures. Furthermore, the ecological roles of many floral visitors remain poorly understood, hindering conservation efforts. In response, in recent years, growing attention has been directed toward the contribution that citizens can give in support of pollinator research. An increasing number of projects have adopted a Citizen Science approach to enable large-scale data collection. The LIFE 4 Pollinators project (LIFE18/GIE/IT/000755) “Involving people to protect wild bees and other pollinators in the Mediterranean” aims to promote the conservation of pollinating insects and entomophilous plants across the Mediterranean region by fostering progressive changes in human practices that threaten wild pollinators. In addition to the implementation of several actions to raise awareness, the project launched a web platform to collect photographic records of flower–insect interaction from the public. The platform is expected to remain active for at least ten years, during which we encourage continuing record submissions by interested bodies. With this data paper we are making the current dataset freely accessible to anyone, committing to periodic online updates.&lt;/p&gt;}, journal={Journal of Pollination Ecology}, author={Barberis, Marta and Bitonto, Fortunato Fulvio and Costantino, Roberto and Bianco, Lorenzo and Birtele, Daniele and Bonifacino, Marco and Cangelmi, Giacomo and Capò, Miquel and Chroni, Athanasia and d’Agostino, Marco and et al.}, year={2025}, month={Nov.}, pages={306–315} }. Accessed at <https://github.com/globalbioticinteractions/life4pollinators/archive/74ddb96b7a611646153cb74d7f3fc58e2290dc52.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Ollerton, J., Trunschke, J. ., Havens, K. ., Landaverde-González, P. ., Keller, A. ., Gilpin, A.-M. ., Rodrigo Rech, A. ., Baronio, G. J. ., Phillips, B. J., Mackin, C. ., Stanley, D. A., Treanore, E. ., Baker, E. ., Rotheray, E. L., Erickson, E. ., Fornoff, F. ., Brearley, F. Q. ., Ballantyne, G. ., Iossa, G. ., Stone, G. N., Bartomeus, I. ., Stockan, J. A., Leguizamón, J., Prendergast, K. ., Rowley, L., Giovanetti, M., de Oliveira Bueno, R., Wesselingh, R. A., Mallinger, R., Edmondson, S., Howard, S. R., Leonhardt, S. D., Rojas-Nossa, S. V., Brett, M., Joaqui, T., Antoniazzi, R., Burton, V. J., Feng, H.-H., Tian, Z.-X., Xu, Q., Zhang, C., Shi, C.-L., Huang, S.-Q., Cole, L. J., Bendifallah, L., Ellis, E. E., Hegland, S. J., Straffon Díaz, S., Lander, T. A. ., Mayr, A. V., Dawson, R. ., Eeraerts, M. ., Armbruster, W. S. ., Walton, B. ., Adjlane, N. ., Falk, S. ., Mata, L. ., Goncalves Geiger, A. ., Carvell, C. ., Wallace, C. ., Ratto, F. ., Barberis, M. ., Kahane, F. ., Connop, S. ., Stip, A. ., Sigrist, M. R. ., Vereecken, N. J. ., Klein, A.-M., Baldock, K. ., & Arnold, S. E. J. . (2022). Pollinator-flower interactions in gardens during the COVID-19 pandemic lockdown of 2020. Journal of Pollination Ecology, 31, 87–96. https://doi.org/10.26786/1920-7603(2022)695. Accessed at <https://github.com/globalbioticinteractions/ollerton2022/archive/7eb71e8e5026ec08c04a69a09860f8927061a8fd.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Baldock, D., Wood, T., Cross, I. & Smit, J. 2018. The Bees of Portugal (Hymenoptera: Apoidea: Anthophila). Entomofauna Supplement 22: 1-164
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas R. N. Nichols et al., 2019. The best wildflowers for wild bees. Journal of Insect Conservation, https://link.springer.com/article/10.1007/s10841-019-00180-8
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas R. N. Nichols et al., 2019. The best wildflowers for wild bees. Journal of Insect Conservation, https://link.springer.com/article/10.1007/s10841-019-00180-8
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas R. H. Gibson et al., 2006. Pollinator webs, plant communities and the conservation of rare plants: Arable weeds as a case study. Journal of Applied Ecology, 43. doi:10.1111/j.1365-2664.2006.01130.x DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas R. H. Gibson et al., 2006. Pollinator webs, plant communities and the conservation of rare plants: Arable weeds as a case study. Journal of Applied Ecology, 43. doi:10.1111/j.1365-2664.2006.01130.x DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI

attractant 3

GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/161387222
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/161408987
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/161687680

crop interaction 197

GloBI hasHost Papaver rhoeas https://mycoportal.org/portal/collections/individual/index.php?occid=11626609
GloBI hasHost Papaver rhoeas https://mycoportal.org/portal/collections/individual/index.php?occid=14691904
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2664.13658 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas Ollerton, J., Trunschke, J. ., Havens, K. ., Landaverde-González, P. ., Keller, A. ., Gilpin, A.-M. ., Rodrigo Rech, A. ., Baronio, G. J. ., Phillips, B. J., Mackin, C. ., Stanley, D. A., Treanore, E. ., Baker, E. ., Rotheray, E. L., Erickson, E. ., Fornoff, F. ., Brearley, F. Q. ., Ballantyne, G. ., Iossa, G. ., Stone, G. N., Bartomeus, I. ., Stockan, J. A., Leguizamón, J., Prendergast, K. ., Rowley, L., Giovanetti, M., de Oliveira Bueno, R., Wesselingh, R. A., Mallinger, R., Edmondson, S., Howard, S. R., Leonhardt, S. D., Rojas-Nossa, S. V., Brett, M., Joaqui, T., Antoniazzi, R., Burton, V. J., Feng, H.-H., Tian, Z.-X., Xu, Q., Zhang, C., Shi, C.-L., Huang, S.-Q., Cole, L. J., Bendifallah, L., Ellis, E. E., Hegland, S. J., Straffon Díaz, S., Lander, T. A. ., Mayr, A. V., Dawson, R. ., Eeraerts, M. ., Armbruster, W. S. ., Walton, B. ., Adjlane, N. ., Falk, S. ., Mata, L. ., Goncalves Geiger, A. ., Carvell, C. ., Wallace, C. ., Ratto, F. ., Barberis, M. ., Kahane, F. ., Connop, S. ., Stip, A. ., Sigrist, M. R. ., Vereecken, N. J. ., Klein, A.-M., Baldock, K. ., & Arnold, S. E. J. . (2022). Pollinator-flower interactions in gardens during the COVID-19 pandemic lockdown of 2020. Journal of Pollination Ecology, 31, 87–96. https://doi.org/10.26786/1920-7603(2022)695. Accessed at <https://github.com/globalbioticinteractions/ollerton2022/archive/7eb71e8e5026ec08c04a69a09860f8927061a8fd.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/1789428
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/288030757
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/162356651
GloBI visitsFlowersOf Papaver rhoeas @article{Barberis_Bitonto_Costantino_Bianco_Birtele_Bonifacino_Cangelmi_Capò_Chroni_d’Agostino_et al._2025, title={Insect-flower interactions in the Mediterranean area: a Citizen Science dataset collated within the LIFE 4 Pollinators project}, volume={39}, url={https://www.pollinationecology.org/index.php/jpe/article/view/872}, DOI={10.26786/1920-7603(2025)872}, abstractNote={&lt;p&gt;Pollinators play a vital role in most terrestrial ecosystems, supporting wild plant communities and enhancing agricultural yields. However, despite their ecological and economic importance, they have been experiencing an alarming decline over the past decades. The Mediterranean region, known for harboring highly diverse communities of plants and pollinators, is particularly vulnerable due to intense anthropogenic pressures. Furthermore, the ecological roles of many floral visitors remain poorly understood, hindering conservation efforts. In response, in recent years, growing attention has been directed toward the contribution that citizens can give in support of pollinator research. An increasing number of projects have adopted a Citizen Science approach to enable large-scale data collection. The LIFE 4 Pollinators project (LIFE18/GIE/IT/000755) “Involving people to protect wild bees and other pollinators in the Mediterranean” aims to promote the conservation of pollinating insects and entomophilous plants across the Mediterranean region by fostering progressive changes in human practices that threaten wild pollinators. In addition to the implementation of several actions to raise awareness, the project launched a web platform to collect photographic records of flower–insect interaction from the public. The platform is expected to remain active for at least ten years, during which we encourage continuing record submissions by interested bodies. With this data paper we are making the current dataset freely accessible to anyone, committing to periodic online updates.&lt;/p&gt;}, journal={Journal of Pollination Ecology}, author={Barberis, Marta and Bitonto, Fortunato Fulvio and Costantino, Roberto and Bianco, Lorenzo and Birtele, Daniele and Bonifacino, Marco and Cangelmi, Giacomo and Capò, Miquel and Chroni, Athanasia and d’Agostino, Marco and et al.}, year={2025}, month={Nov.}, pages={306–315} }. Accessed at <https://github.com/globalbioticinteractions/life4pollinators/archive/74ddb96b7a611646153cb74d7f3fc58e2290dc52.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/298409445
GloBI pollinates Papaver rhoeas Bertrand, C., Eckerter, P. W., Ammann, L., Entling, M. H., Gobet, E., Herzog, F., Mestre, L., Tinner, W., & Albrecht, M. (2019). Data from: Seasonal shifts and complementary use of pollen sources by two bee, a lacewing and a ladybeetle species in European agricultural landscapes (Version 1, p. 359813 bytes) [Dataset]. Dryad. https://doi.org/10.5061/DRYAD.6836P06 DOI
GloBI hasHost Papaver rhoeas https://mycoportal.org/portal/collections/individual/index.php?occid=3613767
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/297061996
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/79783797
GloBI visitsFlowersOf Papaver rhoeas Russo, Laura; Fitzpatrick, Una; Larkin, Michelle et al. (2022). Database of plant-flower visitor interactions from Ireland [Dataset]. Dryad. https://doi.org/10.5061/dryad.kwh70rz47. Accessed at <https://github.com/globalbioticinteractions/russo2022/archive/1bd53f013d878a3ebfdf1126e2708558973790f6.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/325723939
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/69718331
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI interactsWith Papaver rhoeas Tri-Trophic Thematic Collection Network, 2014 (and updates). Version: 2016-03-08. http://tcn.amnh.org/. National Science Foundation grant(s) EF#1115081, EF#1115103, EF#1115080, EF#1115144, EF#1115191, EF#1115104, EF#1115115
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/214389602
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/164675121
GloBI eats Papaver rhoeas Neff, F., Brändle, M., Ambarli, D., Ammer, C., Bauhus, J., Boch, S., Hölzel, N., Klaus, V. H., Kleinebecker, T., Prati, D., Schall, P., Schäfer, D., Schulze, E. D., Seibold, S., Simons, N. K., Weisser, W. W., Pellissier, L., & Gossner, M. M. (2021). Changes in plant-herbivore network structure and robustness along land-use intensity gradients in grasslands and forests. Science Advances, 7(20), 18. https://doi.org/10.1126/SCIADV.ABF3985/SUPPL_FILE/ABF3985_SM.PDF DOI
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/295343657
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/283857037
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/226849903
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/5538718
GloBI pollinates Papaver rhoeas doi:10.1007/s00442-022-05151-6 DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/82045131
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/82045131
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/82045131
GloBI pollinates Papaver rhoeas doi:10.1002/ecy.2569 DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/219752351
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/325765509
GloBI pollinates Papaver rhoeas doi:10.1007/s00442-022-05151-6 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visits Papaver rhoeas https://www.inaturalist.org/observations/168641381
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/240265736
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2664.13658 DOI
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI pollinates Papaver rhoeas doi:10.1111/ele.12657 DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/45504123
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/52304441
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/128549745
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2664.13658 DOI
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2435.14160 DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/78374415
GloBI interactsWith Episyrphus balteatus https://www.inaturalist.org/observations/61218426
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI parasiteOf Papaver rhoeas Dennis, R.W.G.. 1995. Fungi of the South East England. Royal Botanic Gardens, Kew
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/153206112
GloBI pollinates Papaver rhoeas doi:10.1111/ele.12657 DOI
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/259148565
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/163668446
GloBI pollinates Papaver rhoeas Lanuza et al. (2025), EuPPollNet: A European Database of Plant-Pollinator Networks. Global Ecol Biogeogr, 34: e70000. https://doi.org/10.1111/geb.70000. Accessed at <https://github.com/ElPea9/EuPPollNet/archive/df446ce3a2b0b0753777531aee32b965e41ebd7b.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas https://www.inaturalist.org/observations/254324734
GloBI pollinates Papaver rhoeas doi:10.1111/1365-2435.14160 DOI
GloBI visitsFlowersOf Papaver rhoeas T.J. Wood et al., 2017. An assessment of historical and contemporary diet breadth in polylectic Andrena bee species. Biological Conservation, doi:10.1016/j.biocon.2017.09.009 DOI
GloBI interactsWith Papaver rhoeas Tri-Trophic Thematic Collection Network, 2014 (and updates). Version: 2016-03-08. http://tcn.amnh.org/. National Science Foundation grant(s) EF#1115081, EF#1115103, EF#1115080, EF#1115144, EF#1115191, EF#1115104, EF#1115115
GloBI eats Papaver rhoeas Neff, F., Brändle, M., Ambarli, D., Ammer, C., Bauhus, J., Boch, S., Hölzel, N., Klaus, V. H., Kleinebecker, T., Prati, D., Schall, P., Schäfer, D., Schulze, E. D., Seibold, S., Simons, N. K., Weisser, W. W., Pellissier, L., & Gossner, M. M. (2021). Changes in plant-herbivore network structure and robustness along land-use intensity gradients in grasslands and forests. Science Advances, 7(20), 18. https://doi.org/10.1126/SCIADV.ABF3985/SUPPL_FILE/ABF3985_SM.PDF DOI
GloBI interactsWith Papaver rhoeas Tri-Trophic Thematic Collection Network, 2014 (and updates). Version: 2016-03-08. http://tcn.amnh.org/. National Science Foundation grant(s) EF#1115081, EF#1115103, EF#1115080, EF#1115144, EF#1115191, EF#1115104, EF#1115115
GloBI visitsFlowersOf Papaver rhoeas M. E. Hanley et al., 2008. Breeding system, pollinator choice and variation in pollen quality in British herbaceous plants. Functional Ecology, 22. doi:10.1111/j.1365-2435.2008.01415.x DOI
GloBI hasHost Papaver rhoeas https://www.inaturalist.org/observations/166836480
GloBI visitsFlowersOf Papaver rhoeas R.E. Walton et al., 2020. Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape.. Biology Letters, 16. doi:10.1098/rsbl.2019.0877 DOI
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI visitsFlowersOf Papaver rhoeas R.E. Walton et al., 2020. Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape.. Biology Letters, 16. doi:10.1098/rsbl.2019.0877 DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI eats Papaver rhoeas https://www.inaturalist.org/observations/230560246
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI eats Papaver rhoeas Ellis, W. N. (2022). Plant Parasites of Europe – leafminers, galls and fungi [Database]. https://bladmineerders.nl/
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas R. N. Nichols et al., 2019. The best wildflowers for wild bees. Journal of Insect Conservation, https://link.springer.com/article/10.1007/s10841-019-00180-8
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/69718331
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas R.F. Comont et al., 2019. Bumblebee Conservation Trust: BeeWalk Annual Report 2020. Bumblebee Conservation Trust, doi:10.15468/xde3qb DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI eats Papaver rhoeas Ellis, W. N. (2022). Plant Parasites of Europe – leafminers, galls and fungi [Database]. https://bladmineerders.nl/
GloBI interactsWith Papaver rhoeas https://www.inaturalist.org/observations/166836480
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas @article{Barberis_Bitonto_Costantino_Bianco_Birtele_Bonifacino_Cangelmi_Capò_Chroni_d’Agostino_et al._2025, title={Insect-flower interactions in the Mediterranean area: a Citizen Science dataset collated within the LIFE 4 Pollinators project}, volume={39}, url={https://www.pollinationecology.org/index.php/jpe/article/view/872}, DOI={10.26786/1920-7603(2025)872}, abstractNote={&lt;p&gt;Pollinators play a vital role in most terrestrial ecosystems, supporting wild plant communities and enhancing agricultural yields. However, despite their ecological and economic importance, they have been experiencing an alarming decline over the past decades. The Mediterranean region, known for harboring highly diverse communities of plants and pollinators, is particularly vulnerable due to intense anthropogenic pressures. Furthermore, the ecological roles of many floral visitors remain poorly understood, hindering conservation efforts. In response, in recent years, growing attention has been directed toward the contribution that citizens can give in support of pollinator research. An increasing number of projects have adopted a Citizen Science approach to enable large-scale data collection. The LIFE 4 Pollinators project (LIFE18/GIE/IT/000755) “Involving people to protect wild bees and other pollinators in the Mediterranean” aims to promote the conservation of pollinating insects and entomophilous plants across the Mediterranean region by fostering progressive changes in human practices that threaten wild pollinators. In addition to the implementation of several actions to raise awareness, the project launched a web platform to collect photographic records of flower–insect interaction from the public. The platform is expected to remain active for at least ten years, during which we encourage continuing record submissions by interested bodies. With this data paper we are making the current dataset freely accessible to anyone, committing to periodic online updates.&lt;/p&gt;}, journal={Journal of Pollination Ecology}, author={Barberis, Marta and Bitonto, Fortunato Fulvio and Costantino, Roberto and Bianco, Lorenzo and Birtele, Daniele and Bonifacino, Marco and Cangelmi, Giacomo and Capò, Miquel and Chroni, Athanasia and d’Agostino, Marco and et al.}, year={2025}, month={Nov.}, pages={306–315} }. Accessed at <https://github.com/globalbioticinteractions/life4pollinators/archive/74ddb96b7a611646153cb74d7f3fc58e2290dc52.zip> on 23 May 2026.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Ollerton, J., Trunschke, J. ., Havens, K. ., Landaverde-González, P. ., Keller, A. ., Gilpin, A.-M. ., Rodrigo Rech, A. ., Baronio, G. J. ., Phillips, B. J., Mackin, C. ., Stanley, D. A., Treanore, E. ., Baker, E. ., Rotheray, E. L., Erickson, E. ., Fornoff, F. ., Brearley, F. Q. ., Ballantyne, G. ., Iossa, G. ., Stone, G. N., Bartomeus, I. ., Stockan, J. A., Leguizamón, J., Prendergast, K. ., Rowley, L., Giovanetti, M., de Oliveira Bueno, R., Wesselingh, R. A., Mallinger, R., Edmondson, S., Howard, S. R., Leonhardt, S. D., Rojas-Nossa, S. V., Brett, M., Joaqui, T., Antoniazzi, R., Burton, V. J., Feng, H.-H., Tian, Z.-X., Xu, Q., Zhang, C., Shi, C.-L., Huang, S.-Q., Cole, L. J., Bendifallah, L., Ellis, E. E., Hegland, S. J., Straffon Díaz, S., Lander, T. A. ., Mayr, A. V., Dawson, R. ., Eeraerts, M. ., Armbruster, W. S. ., Walton, B. ., Adjlane, N. ., Falk, S. ., Mata, L. ., Goncalves Geiger, A. ., Carvell, C. ., Wallace, C. ., Ratto, F. ., Barberis, M. ., Kahane, F. ., Connop, S. ., Stip, A. ., Sigrist, M. R. ., Vereecken, N. J. ., Klein, A.-M., Baldock, K. ., & Arnold, S. E. J. . (2022). Pollinator-flower interactions in gardens during the COVID-19 pandemic lockdown of 2020. Journal of Pollination Ecology, 31, 87–96. https://doi.org/10.26786/1920-7603(2022)695. Accessed at <https://github.com/globalbioticinteractions/ollerton2022/archive/7eb71e8e5026ec08c04a69a09860f8927061a8fd.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Baldock, D., Wood, T., Cross, I. & Smit, J. 2018. The Bees of Portugal (Hymenoptera: Apoidea: Anthophila). Entomofauna Supplement 22: 1-164
GloBI visitsFlowersOf Papaver rhoeas G.N. Stone et al., 2017. Dataset: Insect Pollinators Archive. Natural History Museum Data Portal (data.nhm.ac.uk). NHM Portal, doi:10.5519/0062900 DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas R. N. Nichols et al., 2019. The best wildflowers for wild bees. Journal of Insect Conservation, https://link.springer.com/article/10.1007/s10841-019-00180-8
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas R. N. Nichols et al., 2019. The best wildflowers for wild bees. Journal of Insect Conservation, https://link.springer.com/article/10.1007/s10841-019-00180-8
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas R. H. Gibson et al., 2006. Pollinator webs, plant communities and the conservation of rare plants: Arable weeds as a case study. Journal of Applied Ecology, 43. doi:10.1111/j.1365-2664.2006.01130.x DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI pollinates Papaver rhoeas Petanidou, T. (1991). Pollination ecology in a phryganic ecosystem. Unp. PhD. Thesis, Aristotelian University, Thessaloniki.
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas R. H. Gibson et al., 2006. Pollinator webs, plant communities and the conservation of rare plants: Arable weeds as a case study. Journal of Applied Ecology, 43. doi:10.1111/j.1365-2664.2006.01130.x DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Balfour, N. J., Castellanos, M. C., Goulson, D., Philippides, A., & Johnson, C. (2022). DoPI: The Database of Pollinator Interactions. Ecology, 103(11), e3801. https://doi.org/10.1002/ecy.3801 DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI
GloBI pollinates Papaver rhoeas Poelen, J. H. Global Biotic Interactions: Interpreted Data Products. Zenodo https://doi.org/10.5281/zenodo.5708970 (2021). DOI
GloBI visitsFlowersOf Papaver rhoeas Richard E. Walton, Carl D. Sayer, Helen Bennion, Jan C. Axmacher; Nocturnal pollinators strongly contribute to pollen transport of wild flowers in an agricultural landscape. Biol Lett 1 May 2020; 16 (5): 20190877. https://doi.org/10.1098/rsbl.2019.0877. Accessed at <https://github.com/globalbioticinteractions/walton2020/archive/c8954ca2555d6fb13c1521c9fd0f50925fc8efe3.zip> on 23 May 2026. DOI

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