From Wikipedia
The Keeling Curve also shows a cyclic variation of about 5 ppmv in each year corresponding to the seasonal change in uptake of CO2 by the world's land vegetation. Most of this vegetation is in the Northern hemisphere, since this is where most of the land is located. From a maximum in May, the level decreases during the northern spring and summer as newplant growth takes carbon dioxide out of the atmosphere through photosynthesis. After reaching a minimum in October, the level rises again in the northern fall and winter as plants and leaves die off and decay, releasing the gas back into the atmosphere.[13]
When C.D. Keeling published his 1960 paper, there did not appear to be any evidence of oceanic absorption. Keeling conjectured that this might be attributable to fluctuations in the causation of the seasonal variation, within the small number of years since his measurements had begun. However it is now understood that allowance should be made for about 50% absorption by the oceanic sinks.[17]
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Satellite derived data of seasonal CO2
Sunday, June 29, 2014
Cooling of Atmosphere Due to CO2 Emission
(behind paywall, found most of it here)
Conclusions
During the latest three millennia, one can observe a clear cooling trend in
the Earth's climate (Keigwin, 1996; Sorokhtin and Ushakov, 2002; Gerhard,
2004; Khiyuk and Chilingar, 2006; Sorokhtin et al., 2007). During this
period, deviations of the global temperature from this trend reached up to
3iC with a clear trend of decreasing global temperature by about 2iC.
Relatively short-term variations in global temperature are mainly caused by
the variations in solar activity and are not linked to the changes in carbon
dioxide content in atmosphere.
the Earth's climate (Keigwin, 1996; Sorokhtin and Ushakov, 2002; Gerhard,
2004; Khiyuk and Chilingar, 2006; Sorokhtin et al., 2007). During this
period, deviations of the global temperature from this trend reached up to
3iC with a clear trend of decreasing global temperature by about 2iC.
Relatively short-term variations in global temperature are mainly caused by
the variations in solar activity and are not linked to the changes in carbon
dioxide content in atmosphere.
Accumulation of large amounts of carbon dioxide in the atmosphere leads to
the cooling, and not to warming of climate, as the proponents of traditional
anthropogenic global warming theory believe (Aeschbach-Hertig, 2006). This
conclusion has a simple physical explanation: when the infrared radiation is
absorbed by the molecules of greenhouse gases, its energy is transformed
into thermal expansion of air, which causes convective fluxes of air masses
restoring the adiabatic distribution of temperature in the troposphere. Our
estimates show that release of small amounts of carbon dioxide (several
hundreds ppm), which are typical for the scope of anthropogenic emission,
does not influence the global temperature of Earth's atmosphere.
the cooling, and not to warming of climate, as the proponents of traditional
anthropogenic global warming theory believe (Aeschbach-Hertig, 2006). This
conclusion has a simple physical explanation: when the infrared radiation is
absorbed by the molecules of greenhouse gases, its energy is transformed
into thermal expansion of air, which causes convective fluxes of air masses
restoring the adiabatic distribution of temperature in the troposphere. Our
estimates show that release of small amounts of carbon dioxide (several
hundreds ppm), which are typical for the scope of anthropogenic emission,
does not influence the global temperature of Earth's atmosphere.
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