ABSTRACT
To understand better how complex interactions between environmental variables affect the energy balance of small diurnal animals, we studied the effects of the absence and presence of 950 W m−2 simulated solar radiation combined with wind speeds ranging from 0.25 to 1.00 m s−1 on the metabolic rate and body temperature of the round-tailed ground squirrel Spermophilus tereticaudus. As wind speed increased from 0.25 to 1.00 m s−1, metabolic heat production increased by 0.94 W in the absence of solar radiation and by 0.98 W in the presence of 950 W m−2 simulated solar radiation. Exposure to simulated solar radiation reduced metabolic heat production by 0.68 W at a wind speed of 0.25 m s−1, by 0.64 W at 0.50 m s−1 and by 0.64 W at 1.00 m s−1. Body temperature was significantly affected by environmental conditions, ranging from 32.5 °C at a wind speed of 1.0 m s−1 and no irradiance to 35.6 °C at a wind speed of 0.50 m s−1 with 950 W m−2 short-wave irradiance.
In addition, several unusual findings resulted from this study. The coat of S. tereticaudus is very sparse, and the observed heat transfer of 5.68±0.37 W m−2 °C−1 (mean ± S.E.M., N=11) is much higher than expected from either allometric equations or comparative studies with other rodents of similar mass. Solar heat gain was remarkably low, equalling only 10 % of intercepted radiation and suggesting a remarkably high regional thermal resistance at the tissue level. Animals remained normally active and alert at body temperatures as low as 32.5 °C. These findings suggest a unique combination of adaptations that allow S. tereticaudus to exploit a harsh desert environment.
