Wool length and radiant heating effects in sheep

J. T. Parer

doi:10.1017/S0021859600015926

Extract

1. When Merinos of varying wool lengths were exposed at constant air temperature of 36° C. (c. 97° F.) to infra-red radiation of energy equivalent to that which they might receive from the sun, the following responses were noted:

(a) A very highly significant (P < 0·001) inverse relationship between respiration rate and wool length.

(b) A non-significant inverse relationship between rectal temperature and wool length.

(d) A very highly significant (P < 0·001) inverse relationship between back-skin temperature and wool length.

Thus, the length of wool determines to a large extent the degree of protection given to the sheep against radiant heat.

2. The rate of conduction of heat per unit area through the back wool in different sheep was hyperbolically related to wool length. Below 1 cm. woollength heat was taken up very rapidly; beyond 4 cm., increasing wool length afforded negligible additional protection.

References

REFERENCES

Bligh, J. (1959). J. Physiol. 146, 142.Google Scholar

Hutchinson, J. C. D., Bennett, J. W. & Wodzicka-Tomaszewska, M. (1960). Proc. Aust. Soc. Anim. Prod. 3, 199.Google Scholar

Lee, D. H. K. (1953). Manual of Field Studies on the Heat Tolerance of Domestic Animals. F.A.O. Development Paper, no. 38.Google Scholar

Macfarlane, W. V., Morris, R. J. H. & Howard, B. (1956). Nature, Lond., 178, 304.CrossRef Google Scholar

Macfarlane, W. V., Morris, R. J. H. & Howard, B. (1958). Aust. J. Agric. Res. 9, 217.CrossRef Google Scholar

Parer, J. T. (1961). Thesis, Master of Rural Science Degree, University of New England, N.S.W., Australia.Google Scholar

Priestley, C. H. B. (1957). Aust. J. Agric. Res. 8, 271.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

THWAITES, C. J. 1966. Fleece Length and the Reactions of Sheep to Wet and Dry Heat. Nature, Vol. 211, Issue. 5052, p. 997.

Haring, F. and Gruhn, R. 1966. Züchterische Maßnahmen zur Verbesserung der Schafpopulation unter Berücksichtigung klimatischer Standortbedingungen1. Zeitschrift für Tierzüchtung und Züchtungsbiologie, Vol. 83, Issue. 1-4, p. 1.

Thwaites, C. J. 1967. Age and heat tolerance in sheep. International Journal of Biometeorology, Vol. 11, Issue. 2, p. 209.

Thwaites, C.J. 1967. Fleece Length and the Reactions of Sheep to Elevated Humidity and Radiant Heating at High Ambient Temperatures. Research in Veterinary Science, Vol. 8, Issue. 4, p. 463.

RICHARDS, S. A. 1970. THE BIOLOGY AND COMPARATIVE PHYSIOLOGY OF THERMAL PANTING. Biological Reviews, Vol. 45, Issue. 2, p. 223.

1975. Animal Science. p. 353.

Younis, A. A. Al-Mahmoud, F. El-Tawil, E. A. and El-Shobokshy, A. S. 1977. Performance and heat tolerance of Awassi lambs as affected by early shearing. The Journal of Agricultural Science, Vol. 89, Issue. 3, p. 565.

McArthur, A.J. 1991. Forestry and shelter for livestock. Forest Ecology and Management, Vol. 45, Issue. 1-4, p. 93.

Kasa, I.W. and Thwaites, C.J. 1992. The effect of infra-red radiation on rectal temperature and respiration rate of unacclimated female new zealand white rabbits. Journal of Thermal Biology, Vol. 17, Issue. 6, p. 293.

Grenot, Claude J. 1992. Ecophysiological characteristics of large herbivorous mammals in arid Africa and the Middle East. Journal of Arid Environments, Vol. 23, Issue. 2, p. 125.

Wheeler, P.E. 1992. The influence of the loss of functional body hair on the water budgets of early hominids. Journal of Human Evolution, Vol. 23, Issue. 5, p. 379.

Maloney, Shane K. and Dawson, Terence J. 1995. The heat load from solar radiation on a large, diurnally active bird, the emu (Dromaius novaehollandiae). Journal of Thermal Biology, Vol. 20, Issue. 5, p. 381.

2004. Livestock Biodiversity. p. 217.

Kasa I. W., and Thwaites C. J. 2010. THE EFFECT OF INFRA-RED RADIATION ON RECTAL, SKIN AND HAIR-TIP TEMPERATURES OF RABBITS.. World Rabbit Science, Vol. 1, Issue. 4,

Suhair, S. Mohammed and Abdalla, M. Abdelatif 2013. Effects of Seasonal Changes and Shearing on Thermoregulation, Blood Constituents and Semen Characteristics of Desert Rams (Ovis aries). Pakistan Journal of Biological Sciences, Vol. 16, Issue. 24, p. 1884.

Spengler, D. Strobel, H. Axt, H. and Voigt, K. 2015. Wasserbedarf, Wasserversorgung und Thermoregulation kleiner Wiederkäuer bei Weidehaltung. Tierärztliche Praxis Ausgabe G: Großtiere / Nutztiere, Vol. 43, Issue. 01, p. 49.

Armengol, M.F. López Sabino, G.A. Forquera, J.C. de la Casa, A. and Aisen, E.G. 2015. Sperm head ellipticity as a heat stress indicator in Australian Merino rams (Ovis aries) in Northern Patagonia, Argentina. Theriogenology, Vol. 83, Issue. 4, p. 553.

Moore, K.E. Maloney, S.K. and Blache, D. 2015. High follicle density does not decrease sweat gland density in Huacaya alpacas. Journal of Thermal Biology, Vol. 47, Issue. , p. 1.

García, Juan A. Romero, Agustín Uzal, Francisco A. Tarigo, Laura Affolter, Verena K. and Dutra, Fernando 2019. Solar‐induced dorsal skin necrosis in sheep. Veterinary Dermatology, Vol. 30, Issue. 5, p. 442.

Aguilar, Lourdes-Angelica Collins, Teresa Dunston-Clarke, Emma J. Wickham, Sarah L. Fleming, Patricia A. and Barnes, Anne L. 2020. Impact of shearing sheep on feeding and behaviour during the pre-embarkment feedlot phase of live export. Animal Production Science, Vol. 60, Issue. 7, p. 936.

Download full list

Article contents

Wool length and radiant heating effects in sheep

Extract

Access options

References

REFERENCES

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Wool length and radiant heating effects in sheep

Extract

Access options

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests