Abstract
Some tenebrionind beetles inhabiting the Namib desert are known for using their body to collect water droplets from wind-blown fogs. We aim to determine whether dew water collection is also possible for desert insects. For this purpose, we investigated the infra-red emissivity, and the wetting and structural properties, of the surface of the elytra of a preserved specimen of Physasterna cribripes (Tenebrionidæ) beetle, where the macro-structure appears as a series of “bumps”, with “valleys” between them. Dew formation experiments were carried out in a condensation chamber. The surface properties (infra-red emissivity, wetting properties) were dominated by the wax at the elytra surface and, to a lower extent, its micro-structure. We performed scanning electron microscope on histological sections and determined the infra-red emissivity using a scanning pyrometer. The emissivity measured (0.95±0.07 between 8–14μm) was close to the black body value. Dew formation occurred on the insect’s elytra, which can be explained by these surface properties. From the surface coverage of the condensed drops it was found that dew forms primarily in the valleys between the bumps. The difference in droplet nucleation rate between bumps and valleys can be attributed to the hexagonal microstructure on the surface of the valleys, whereas the surface of the bumps is smooth. The drops can slide when they reach a critical size, and be collected at the insect's mouth.
Graphical abstract
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
W.J. Hamilton, M.K. Seely, Nature 262, 284 (1976).
M. Seely, J.R. Henschel, W.J. Hamilton, South African J. Sci. 101, 570 (2005).
A.R. Parker, C.R. Lawrence, Nature 414, 33 (2001).
R.P. Garrod, L.G. Harris, W.C.E. Schofield, J. McGettrick, L.J. Ward, D.O.H. Teare, J.P.S. Badyal, Langmuir 23, 689 (2007).
T. Nørgaard, M. Dacke, Front. Zool. 7, 23 (2010).
C. Dorrer, J. Rühe, Langmuir 24, 6154 (2008).
L. Zhai, M.C. Berg, F.C. Cebeci, Y. Kim, J.M. Milwid, M.F. Rubner, R.E. Cohen, Nano Lett. 6, 1213 (2006).
http://www.wunderground.com/ (The Weather Underground, Inc.). Historical record (2013) for station id. 68106 of World Meteorological Organization.
M. Muselli, D. Beysens, M. Mileta, I. Milimouk, Atmos. Res. 92, 455 (2009).
D. Beysens, M. Muselli, V. Nikolayev, R. Narhe, I. Milimouk, Atmos. Res. 73, 1 (2005).
J. Houghton, The Physics of Atmospheres, 3rd ed. (Cambridge University Press, 2002).
V.L. Hunt, G.D. Lock, S.G. Pickering, A.K. Charnley, J. Thermal Biol. 36, 443 (2011).
H. Zhao, D. Beysens, Langmuir 11, 627 (1995).
D. Beysens, C. R. Phys. 7, 1082 (2006).
B.J. Briscoe, K.P. Galvin, Phys. Rev. A 43, 1906 (1991).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Guadarrama-Cetina, J., Mongruel, A., Medici, M.G. et al. Dew condensation on desert beetle skin. Eur. Phys. J. E 37, 109 (2014). https://doi.org/10.1140/epje/i2014-14109-y
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1140/epje/i2014-14109-y