141 results on '"Schweiger, Oliver"'
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2. Landscape simplification leads to loss of plant–pollinator interaction diversity and flower visitation frequency despite buffering by abundant generalist pollinators
3. A niche-based approach for evaluating the mechanisms of community stability in butterflies
4. Modern Approaches to the Monitoring of Biоdiversity (MAMBO)
5. Figure 2 from: Høye TT, August T, Balzan MV, Biesmeijer K, Bonnet P, Breeze TD, Dominik C, Gerard F, Joly A, Kalkman V, Kissling WD, Metodiev T, Moeslund J, Potts S, Roy DB, Schweiger O, Senapathi D, Settele J, Stoev P, Stowell D (2023) Modern Approaches to the Monitoring of Biоdiversity (MAMBO). Research Ideas and Outcomes 9: e116951. https://doi.org/10.3897/rio.9.e116951
6. Figure 4 from: Høye TT, August T, Balzan MV, Biesmeijer K, Bonnet P, Breeze TD, Dominik C, Gerard F, Joly A, Kalkman V, Kissling WD, Metodiev T, Moeslund J, Potts S, Roy DB, Schweiger O, Senapathi D, Settele J, Stoev P, Stowell D (2023) Modern Approaches to the Monitoring of Biоdiversity (MAMBO). Research Ideas and Outcomes 9: e116951. https://doi.org/10.3897/rio.9.e116951
7. Figure 3 from: Høye TT, August T, Balzan MV, Biesmeijer K, Bonnet P, Breeze TD, Dominik C, Gerard F, Joly A, Kalkman V, Kissling WD, Metodiev T, Moeslund J, Potts S, Roy DB, Schweiger O, Senapathi D, Settele J, Stoev P, Stowell D (2023) Modern Approaches to the Monitoring of Biоdiversity (MAMBO). Research Ideas and Outcomes 9: e116951. https://doi.org/10.3897/rio.9.e116951
8. Figure 1 from: Høye TT, August T, Balzan MV, Biesmeijer K, Bonnet P, Breeze TD, Dominik C, Gerard F, Joly A, Kalkman V, Kissling WD, Metodiev T, Moeslund J, Potts S, Roy DB, Schweiger O, Senapathi D, Settele J, Stoev P, Stowell D (2023) Modern Approaches to the Monitoring of Biоdiversity (MAMBO). Research Ideas and Outcomes 9: e116951. https://doi.org/10.3897/rio.9.e116951
9. Pesticide use negatively affects bumble bees across European landscapes
10. High rates of nectar depletion in summer grasslands indicate competitive conditions for pollinators
11. PoshBee Toolbox: A portfolio of high quality methodologies, tools, and practice guides for pollinators
12. How Many Butterflies Will Lose Their Habitats?
13. Rice Ecosystem Services in South-East Asia: The LEGATO Project, Its Approaches and Main Results with a Focus on Biocontrol Services
14. Minimising Risks of Global Change by Enhancing Resilience of Pollinators in Agricultural Systems
15. Mechanisms underpinning community stability along a latitudinal gradient: insights from a niche‐based approach
16. Linking Biodiversity Research Communities
17. Design and Planning of a Transdisciplinary Investigation into Farmland Pollinators: Rationale, Co-Design, and Lessons Learned
18. Bioclimatic context of species' populations determines community stability
19. Honey bees and climate explain viral prevalence in wild bee communities on a continental scale
20. Improving the Resilience of Fast Failover Routing
21. On Comparing and Enhancing Two Common Approaches to Network Community Detection
22. Pollinator sampling methods influence community patterns assessments by capturing species with different traits and at different abundances
23. Pathways for Novel Epidemiology: Plant–Pollinator–Pathogen Networks and Global Change
24. Supplementary material 1 from: Vanderplanck M, Michez D, Albrecht M, Attridge E, Babin A, Bottero I, Breeze T, Brown M, Chauzat M-P, Cini E, Costa C, De la Rua P, de Miranda JR, Di Prisco G, Dominik C, Dzul D, Fiordaliso W, Gennaux S, Ghisbain G, Hodge S, Klein A-M, Knapp J, Knauer A, Laurent M, Lefebvre V, Mänd M, Martinet B, Martinez-Lopez V, Medrzycki P, Pereira Peixoto MH, Potts SG, Przybyla K, Raimets R, Rundlöf M, Schweiger O, Senapathi D, Serrano J, Stout JC, Straw EA, Tamburini G, Toktas Y, Gérard M (2021) Monitoring bee health in European agro-ecosystems using wing morphology and fat bodies. One Ecosystem 6: e63653. https://doi.org/10.3897/oneeco.6.e63653
25. Monitoring bee health in European agro-ecosystems using wing morphology and fat bodies
26. Supplementary material 2 from: Vanderplanck M, Michez D, Albrecht M, Attridge E, Babin A, Bottero I, Breeze T, Brown M, Chauzat M-P, Cini E, Costa C, De la Rua P, de Miranda JR, Di Prisco G, Dominik C, Dzul D, Fiordaliso W, Gennaux S, Ghisbain G, Hodge S, Klein A-M, Knapp J, Knauer A, Laurent M, Lefebvre V, Mänd M, Martinet B, Martinez-Lopez V, Medrzycki P, Pereira Peixoto MH, Potts SG, Przybyla K, Raimets R, Rundlöf M, Schweiger O, Senapathi D, Serrano J, Stout JC, Straw EA, Tamburini G, Toktas Y, Gérard M (2021) Monitoring bee health in European agro-ecosystems using wing morphology and fat bodies. One Ecosystem 6: e63653. https://doi.org/10.3897/oneeco.6.e63653
27. Opportunities to improve China’s biodiversity protection laws
28. Klimawandeleffekte heute
29. Klimawandeleffekte morgen
30. Understanding cultural ecosystem services related to farmlands: Expert survey in Europe
31. A new comprehensive trait database of European and Maghreb butterflies, Papilionoidea
32. Scale‐dependent impact of land management on above‐ and belowground biodiversity
33. Assigning occurrence data to cryptic taxa improves climatic niche assessments: Biodecrypt, a new tool tested on European butterflies
34. Pesticides and land cover heterogeneity affect functional group and taxonomic diversity of arthropods in rice agroecosystems
35. Supplementary material 3 from: Datta A, Schweiger O, Kühn I (2020) Origin of climatic data can determine the transferability of species distribution models. NeoBiota 59: 61-76. https://doi.org/10.3897/neobiota.59.36299
36. Supplementary material 1 from: Datta A, Schweiger O, Kühn I (2020) Origin of climatic data can determine the transferability of species distribution models. NeoBiota 59: 61-76. https://doi.org/10.3897/neobiota.59.36299
37. Supplementary material 2 from: Datta A, Schweiger O, Kühn I (2020) Origin of climatic data can determine the transferability of species distribution models. NeoBiota 59: 61-76. https://doi.org/10.3897/neobiota.59.36299
38. Origin of climatic data can determine the transferability of species distribution models
39. Supplementary material 6 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
40. Figure 3 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
41. Supplementary material 1 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
42. Supplementary material 7 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
43. Figure 1 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
44. Supplementary material 3 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
45. Supplementary material 8 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
46. Supplementary material 5 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
47. Figure 2 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
48. Supplementary material 4 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
49. A complete time-calibrated multi-gene phylogeny of the European butterflies
50. Supplementary material 2 from: Wiemers M, Chazot N, Wheat C, Schweiger O, Wahlberg N (2020) A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97-124. https://doi.org/10.3897/zookeys.938.50878
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