RADIATIVE-PHOTOCHEMICAL MODELING OF THE ANNUALLY AVERAGED COMPOSITIONAND TEMPERATURE OF THE GLOBAL ATMOSPHERE DURING THE LAST GLACIAL AND INTERGLACIAL PERIODS
Il. Karol et al., RADIATIVE-PHOTOCHEMICAL MODELING OF THE ANNUALLY AVERAGED COMPOSITIONAND TEMPERATURE OF THE GLOBAL ATMOSPHERE DURING THE LAST GLACIAL AND INTERGLACIAL PERIODS, JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERES, 100(D4), 1995, pp. 7291-7301
Recent measurements of CO2, CH4, and N2O content in Antarctic and Gree
nland ice core air allow the use of an one-dimensional radiative-photo
chemical model to reconstruct the annual global mean vertical distribu
tions of trace gas concentrations for four periods: the contemporary p
eriod of 1985, the preindustrial period of 1850, the last glacial peri
od of 18 ka B.P., and the interglacial period before the latter of 120
-130 ka B.P. In this model reconstruction, the changes in surface air
temperature and tropospheric relative humidity are prescribed, and bot
h dry adiabatic and moist adiabatic lapse rates are used together with
several other external estimates of radiative and photochemical param
eters for these periods. The considerable reduction of greenhouse gas
content in the atmosphere of both glacial and interglacial periods, in
cluding about a 50% reduction of stratospheric moisture in the glacial
, leads to the warming of the middle and upper stratosphere by about 1
1 K and 4 K, in the glacial and interglacial periods, respectively. St
ratospheric composition is found to be little sensitive to possible la
rge variations of CO and NOX surface sources. The ozone mixing ratio d
rops to 10-12 ppbv in the lower troposphere and increases to a maximum
6.0-7.5 ppmv in 40 to 46-km layer, but remains almost the same as in
preindustrial and in 1985 periods in the 20 to 30-km layer. This resul
ts in the approximate conservation of total ozone for all four periods
considered.