The earth rotates round its axis in a span of 24 hours and revolves round the sun in 365 days in a normal year and in 366 days in a leap year. This rotation around its own axis is at an angle and the revolution around the sun is in an elliptical orbit which twice is at a greater distance from the sun 180 degrees or roughly 182 and a half days away from the sun and 180 degrees or roughly again 182 and a half days nearest to the sun again leading to the prospect that the closeness to the sun of the earth would lead to higher temperatures and the distance from the sun again leading to lower temperatures. Now, we know that on the sun’s surface there are solar flares whose occurrence is occasional which means that cases of higher temperatures is evident that may affect the temperatures on the earth which however due to the simultaneous rotation and revolution means that that particular area of the earth does not constantly expose itself to solar flares thus meaning that except for the equatorial and tropical areas which are comparatively hotter in that order to the poles which are supposed to be cooler. The idea of this heating based only on the slanting axis and the elliptical orbiting around the sun is to bring to the fore that more closeness to the sun will make that portion of the earth being warmer but at the same time it is the justification of only closeness and distance from the sun and solar flares occurring in the sun at the time when the particular portion of the earth can be hotter than normal is agreed.
With so many satellites now orbiting the earth, exposure to the sun as having been the cause of higher and lower temperatures on particular portions of the earth can be logged in a data base. Once this sole rotation and revolution pattern of heating of the earth is ascertained beyond doubt along with its intensity, then only can this model be superimposed with the emissions of greenhouse gases to determine for sure the extent of further heating due to the capturing of the sun’s heat by the carbon dioxide that is emitted at various portions of the earth for example where big coal-fired power plants are located and thus where huge quantities of the carbon dioxide is emitted, to quantify the excess heating of the earth at twenty four hour intervals so that those portions of the earth where huge carbon dioxide emissions are experienced due to the billowing of carbon dioxide from the power plants run on coal, thus indicating the extent of extra heating of the surfaces of the earth right through the process of rotation around the axis as well as revolution around the earth. Censors deployed at location of coal-fired power plants can then measure the local heating at those places and then relate them to the other areas that do not emit high quantities of carbon dioxide. This exercise if conducted for a year will definitely throw light on the extent of extra heating due to carbon dioxide emissions that then can be calibrated to predict temperatures around the earth. This model could in turn serve the weatherman with inputs as to how weather patterns around the world will shape up say within a year. It may be inferred that from such a study global warming due to not only exposure to the sun but coupled with the impact of emissions will clearly lead to the guarantee that carbon dioxide trapping of the heat of the sun in the atmosphere contributes to a great measure global warming and climate change.
