Columbiformes
EOL Text
In Great Britain and/or Ireland:
Animal / parasite / ectoparasite
imago of Ornithomya avicularia ectoparasitises Columbiformes
Animal / parasite / ectoparasite
imago of Pseudolynchia garzettae ectoparasitises Columbiformes
Other: major host/prey
| License | http://creativecommons.org/licenses/by-nc-sa/3.0/ |
| Rights holder/Author | BioImages, BioImages - the Virtual Fieldguide (UK) |
| Source | http://www.bioimages.org.uk/html/Columbiformes.htm |
In Great Britain and/or Ireland:
Animal / parasite / ectoparasite
imago of Ornithomya avicularia ectoparasitises Columbiformes
Animal / parasite / ectoparasite
imago of Pseudolynchia garzettae ectoparasitises Columbiformes
Other: major host/prey
| License | http://creativecommons.org/licenses/by-nc-sa/3.0/ |
| Rights holder/Author | BioImages, BioImages - the Virtual Fieldguide (UK) |
| Source | http://www.bioimages.org.uk/html/Columbiformes.htm |
Grooves shed water: doves
The feathers of doves and other birds shed water due to nanoscale grooves on their surfaces.
"According to Prof. Edward Bormashenko from the Department of Physics at the Ariel University Center of Samaria, the surface of a dove's wing - and that of most birds - is the perfect raincoat, keeping water and dirt from sticking to their bodies. Bormashenko's current research into non-stick materials is based on this understanding, and could lead to self-cleaning textiles, and have important implications in the shipping, recreational sports and building industries. Applying techniques from the fields of physics and nanotechnology, Bormashenko has succeeded in duplicating the material found on bird's wings. He calls it a superhydrophobic polymer. 'It's all because of the 'roughness' on the feathers of the bird,' Bormashenko tells ISRAEL21c, explaining that the surface of a bird's feathers are covered in miniscule nano-sized grooves, 100 nm to 10 microns in width. The unique grooves (at angles of 180 degrees), trap a blanket of air around the feather, and prevent liquids from attaching to the wing surface." (Kloosterman 2008)
Learn more about this functional adaptation.
- Pogreb, R; Whyman, G; Barayev, R; Bormashenko, E; Aurbach, D. 2009. A reliable method of manufacturing metallic hierarchical superhydrophobic surfaces. Applied Physics Letters. 94(221902): 221902-1-221092-3.
- Bormashenko, E; Stein, T; Whyman, G; Pogreb, R; Sutovsky, S; Danoch, Y; Shoham, Y; Bormashenko, Y; Sorokov, B; Aurbach, D. 2008. Superhydrophobic metallic surfaces and their wetting properties. Journal of Adhesion Science and Technology. 22: 379-385.
- Bormashenko, E; Stein, T; Whyman, G; Pogreb, R. 2006. Wetting properties of the multiscaled nanostructured polymer and metallic superhydrophobic surfaces. Langmuir. 22: 9982-9985.
- Bormashenko E; Bormashenko Y; Stein T; Whyman G; Bormashenko E. 2007. Why do pigeon feathers repel water? Hydrophobicity of pennae, Cassie-Baxter wetting hypothesis and Cassie-Wenzel capillary-induced wetting transition. Journal of Colloid and Interface Science. 311(1): 212-216.
- Kloosterman, Karin. 2008. Waterproof dove provides inspiration for new stick-free polymer.
| License | http://creativecommons.org/licenses/by-nc/3.0/ |
| Rights holder/Author | (c) 2008-2009 The Biomimicry Institute |
| Source | http://www.asknature.org/strategy/0c11c47c9d26bf39d1712e27ad8a1637 |
Grooves shed water: doves
The feathers of doves and other birds shed water due to nanoscale grooves on their surfaces.
"According to Prof. Edward Bormashenko from the Department of Physics at the Ariel University Center of Samaria, the surface of a dove's wing - and that of most birds - is the perfect raincoat, keeping water and dirt from sticking to their bodies. Bormashenko's current research into non-stick materials is based on this understanding, and could lead to self-cleaning textiles, and have important implications in the shipping, recreational sports and building industries. Applying techniques from the fields of physics and nanotechnology, Bormashenko has succeeded in duplicating the material found on bird's wings. He calls it a superhydrophobic polymer. 'It's all because of the 'roughness' on the feathers of the bird,' Bormashenko tells ISRAEL21c, explaining that the surface of a bird's feathers are covered in miniscule nano-sized grooves, 100 nm to 10 microns in width. The unique grooves (at angles of 180 degrees), trap a blanket of air around the feather, and prevent liquids from attaching to the wing surface." (Kloosterman 2008)
Learn more about this functional adaptation.
- Pogreb, R; Whyman, G; Barayev, R; Bormashenko, E; Aurbach, D. 2009. A reliable method of manufacturing metallic hierarchical superhydrophobic surfaces. Applied Physics Letters. 94(221902): 221902-1-221092-3.
- Bormashenko, E; Stein, T; Whyman, G; Pogreb, R; Sutovsky, S; Danoch, Y; Shoham, Y; Bormashenko, Y; Sorokov, B; Aurbach, D. 2008. Superhydrophobic metallic surfaces and their wetting properties. Journal of Adhesion Science and Technology. 22: 379-385.
- Bormashenko, E; Stein, T; Whyman, G; Pogreb, R. 2006. Wetting properties of the multiscaled nanostructured polymer and metallic superhydrophobic surfaces. Langmuir. 22: 9982-9985.
- Bormashenko E; Bormashenko Y; Stein T; Whyman G; Bormashenko E. 2007. Why do pigeon feathers repel water? Hydrophobicity of pennae, Cassie-Baxter wetting hypothesis and Cassie-Wenzel capillary-induced wetting transition. Journal of Colloid and Interface Science. 311(1): 212-216.
- Kloosterman, Karin. 2008. Waterproof dove provides inspiration for new stick-free polymer.
| License | http://creativecommons.org/licenses/by-nc/3.0/ |
| Rights holder/Author | (c) 2008-2009 The Biomimicry Institute |
| Source | http://www.asknature.org/strategy/0c11c47c9d26bf39d1712e27ad8a1637 |
Barcode of Life Data Systems (BOLD) Stats
Specimen Records: 1197
Specimens with Sequences: 797
Specimens with Barcodes: 743
Species: 155
Species With Barcodes: 116
Public Records: 497
Public Species: 95
Public BINs: 94
Barcode of Life Data Systems (BOLD) Stats
| Specimen Records: | 1,035 | Public Records: | 393 |
| Specimens with Sequences: | 656 | Public Species: | 88 |
| Specimens with Barcodes: | 612 | Public BINs: | 87 |
| Species: | 145 | ||
| Species With Barcodes: | 107 | ||
Collection Sites: world map showing specimen collection locations for Columbiformes