Elytra boost lift, but reduce aerodynamic efficiency in flying beetles.
(2012) In Journal of the Royal Society Interface 9(75). p.2745-2748- Abstract
- Flying insects typically possess two pairs of wings. In beetles, the front pair has evolved into short, hardened structures, the elytra, which protect the second pair of wings and the abdomen. This allows beetles to exploit habitats that would otherwise cause damage to the wings and body. Many beetles fly with the elytra extended, suggesting that they influence aerodynamic performance, but little is known about their role in flight. Using quantitative measurements of the beetle's wake, we show that the presence of the elytra increases vertical force production by approximately 40 per cent, indicating that they contribute to weight support. The wing-elytra combination creates a complex wake compared with previously studied animal wakes. At... (More)
- Flying insects typically possess two pairs of wings. In beetles, the front pair has evolved into short, hardened structures, the elytra, which protect the second pair of wings and the abdomen. This allows beetles to exploit habitats that would otherwise cause damage to the wings and body. Many beetles fly with the elytra extended, suggesting that they influence aerodynamic performance, but little is known about their role in flight. Using quantitative measurements of the beetle's wake, we show that the presence of the elytra increases vertical force production by approximately 40 per cent, indicating that they contribute to weight support. The wing-elytra combination creates a complex wake compared with previously studied animal wakes. At mid-downstroke, multiple vortices are visible behind each wing. These include a wingtip and an elytron vortex with the same sense of rotation, a body vortex and an additional vortex of the opposite sense of rotation. This latter vortex reflects a negative interaction between the wing and the elytron, resulting in a single wing span efficiency of approximately 0.77 at mid downstroke. This is lower than that found in birds and bats, suggesting that the extra weight support of the elytra comes at the price of reduced efficiency. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/2608777
- author
- Johansson, Christoffer LU ; Engel, Sophia LU ; Baird, Emily LU ; Dacke, Marie LU ; Muijres, Florian LU and Hedenström, Anders LU
- organization
- publishing date
- 2012
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- beetles, flight, aerodynamics
- in
- Journal of the Royal Society Interface
- volume
- 9
- issue
- 75
- pages
- 2745 - 2748
- publisher
- The Royal Society of Canada
- external identifiers
-
- wos:000308240400033
- pmid:22593097
- scopus:84866250834
- pmid:22593097
- ISSN
- 1742-5662
- DOI
- 10.1098/rsif.2012.0053
- language
- English
- LU publication?
- yes
- id
- edfcbe99-4d9e-4eaa-880b-557b10c5a839 (old id 2608777)
- date added to LUP
- 2016-04-01 11:07:00
- date last changed
- 2024-05-06 05:11:28
@article{edfcbe99-4d9e-4eaa-880b-557b10c5a839, abstract = {{Flying insects typically possess two pairs of wings. In beetles, the front pair has evolved into short, hardened structures, the elytra, which protect the second pair of wings and the abdomen. This allows beetles to exploit habitats that would otherwise cause damage to the wings and body. Many beetles fly with the elytra extended, suggesting that they influence aerodynamic performance, but little is known about their role in flight. Using quantitative measurements of the beetle's wake, we show that the presence of the elytra increases vertical force production by approximately 40 per cent, indicating that they contribute to weight support. The wing-elytra combination creates a complex wake compared with previously studied animal wakes. At mid-downstroke, multiple vortices are visible behind each wing. These include a wingtip and an elytron vortex with the same sense of rotation, a body vortex and an additional vortex of the opposite sense of rotation. This latter vortex reflects a negative interaction between the wing and the elytron, resulting in a single wing span efficiency of approximately 0.77 at mid downstroke. This is lower than that found in birds and bats, suggesting that the extra weight support of the elytra comes at the price of reduced efficiency.}}, author = {{Johansson, Christoffer and Engel, Sophia and Baird, Emily and Dacke, Marie and Muijres, Florian and Hedenström, Anders}}, issn = {{1742-5662}}, keywords = {{beetles; flight; aerodynamics}}, language = {{eng}}, number = {{75}}, pages = {{2745--2748}}, publisher = {{The Royal Society of Canada}}, series = {{Journal of the Royal Society Interface}}, title = {{Elytra boost lift, but reduce aerodynamic efficiency in flying beetles.}}, url = {{http://dx.doi.org/10.1098/rsif.2012.0053}}, doi = {{10.1098/rsif.2012.0053}}, volume = {{9}}, year = {{2012}}, }