The rotational and vibrational temperatures of the nu(2) and 2-nu(2) m
odes of carbon dioxide in the upper atmosphere have been derived from
transmission spectra measured by the ATMOS instrument on Spacelab 3 ov
er the height range 60-110 km. The rotational and vibrational temperat
ure profiles are found to be nearly identical, which leads to the conc
lusion that the CO2(nu(2)) level is in local thermodynamic equilibrium
(LTE) within the experimental errors up to 95 km, and very nearly so
to at least 110 km. The CO2(2-nu(2)) level is found to be close to LTE
up to at least the upper height limit of its retrieval, i.e., 93 km.
The interpretation of those measurements using a non-LTE model [Lopez-
Puertas et al., 1986] supports a fast rate for the deactivation of CO2
(nu(2)) by atomic oxygen, similar to that derived by Sharma and Winter
steiner [1990]. This provides independent confirmation, from a qualita
tively different type of measurement, of the conclusion of those autho
rs that the radiative cooling of the upper atmospheres of the Earth is
around an order of magnitude greater than our 1986 model predicted. I
t also has implications for thermospheric cooling on the other terrest
rial planets, as well as expanding the possibilities for future remote
sensing of the temperature of the upper mesosphere and lower thermosp
here, since the upper limit which can be sounded is higher than previo
usly believed.