32 A PHYSICAL STUDY OF TH^ FlREFtY. 



This apparent increase in the cooling effect in the more active (flashing) 

 state of the insect is a complex phenomenon requiring further investigation. 

 As it stands, it could not be verified by the iron-constantan thermo-couple 

 measurements on the temperature of the different parts of the body of the 

 insect. The thermo-couple shows, Fig. 13, /l, that the temperature of the 

 insect is lower than the air (this is in agreement with the radiometric obser- 

 vations), and that, used differentially, the temperature of the luminous seg- 

 ments is higher than the rest of the body ; but it was not possible to show 

 with certainty whether the temperature of the luminous segments varied 

 (apparently decreased by the radiometric test) during the act of flashing. 



After trying out these heat-conduction effects with the insect close to the 

 vacuum thermo-element, the radiometric apparatus was arranged so that a 

 mirror, 15 cm. in focal length and 10 cm. diameter, projected an image of an 

 opening (2.5 mm. diameter) in a heavy black cardboard upon the active 

 thermo- junction. The whole was covered so that no radiation, except that 

 which passed through the opening in the cardboard, could fall upon the 

 thermo-element. The firefly was then held with the luminous segments 

 over the opening in the cardboard. Both glowing and flashing specimens 

 were examined, but in only one instance was any deflection (a kick) observed 

 that might be interpreted as possibly being due to the light (flash) from the 

 firefly. It was therefore concluded that, since the glass wall of the bismuth- 

 platinum thermo-element absorbed the long waves, no radiations less than 

 TfH were observable. The radiations which are greater than ^fx would fall in 

 the category of "animal heat," which will now be discussed. 



Langley avoided the effect of "animal heat" by interposing a glass screen, 

 which prevented an interchange between the insect and the radiometer of 

 radiations greater than 3 to 4^1. It has just been noticed that under certain 

 conditions, when the insect was near (or touching) the glass walls of the 

 thermopile, the deflection of the galvanometer indicated that the sensitive 

 junction was losing heat by radiation; and, from the slowness of the action, 

 that this was due to the local cooling of the glass wall surrounding it. Evi- 

 dently conditions might be brought about whereby a heating effect, caused 

 by a true radiation from the insect, might be counterbalanced by a cooling 

 effect (conduction) due to a difference in temperature between the insect 

 and the radiometer, the latter being at the higher temperature. Further- 

 more, if the light production is a biochemical process, as some believe it to be, 

 it is important to know whether this low temperature is due to the fact that 

 we are dealing with a "cold-blooded" animal, or due to an endothermic 

 reaction. Thermometric measurements were accordingly undertaken to 

 determine the nature of the heat distribution in the body of the firefly. The 

 first tests were made radiometrically with the vacuum thermo-element just 

 discussed. It was found that the glowing luminous segments, when sepa- 

 rated from the rest of the insect and placed upon the vacuum thermopile, 

 exerted a certain cooling effect which decreased when life was extinct. An 

 insect on its back caused a cooling, but it was impossible to determine by the 

 vacuum thermo-element whether there was a difference in the temperature 

 of the dark and luminous segments. 



These experiments were continued by exploring the temperature distri- 

 bution in the segments of the insect. For this purpose, thermo-couples of 



