Being closer to, or further away from, the sun has got foc all to do with it. The difference, in percentage terms, is tiny. What is important, is the tilt from the vertical axis. Think on a beam of light, and for arguments sake, every beam of light is a foot wide. When that beam of light is aimed squarely at a surface, it covers an area a foot wide - but if you start to tilt the surface it's hitting, it suddenly covers a bigger area. So the energy it contains is spread thinner, less energy for a given area, hence it's cooler. When we're tilted towards the sun, we have summer, and vice versa.
Also, what's the square root of -1?
I think i know.
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Or if you weigh a whale at a whale weigh station, where would you weigh a pie?
Typing "why do we have seasons" into Google brings up a wealth of images to illustrate the point, as sometimes things can get lost in the explanation. I'm one who needs images to explain something so here's a link to one.http://d1jqu7g1y74ds1.cloudfront.net/wp-content/uploads/2008/09/seasonalvariations.jpgHope it helps
Quote from: richfzs on 05 November 2013, 07:24:37 amBeing closer to, or further away from, the sun has got foc all to do with it. The difference, in percentage terms, is tiny. What is important, is the tilt from the vertical axis. Think on a beam of light, and for arguments sake, every beam of light is a foot wide. When that beam of light is aimed squarely at a surface, it covers an area a foot wide - but if you start to tilt the surface it's hitting, it suddenly covers a bigger area. So the energy it contains is spread thinner, less energy for a given area, hence it's cooler. When we're tilted towards the sun, we have summer, and vice versa.Thick as I am the initial statement is flawed. If you change the angle of a,surface (the earth) to a fixed point (the sun) the distance of the sun will increase along the line of the surface. Thus changing the angle. So distance no matter how insignificant must play a part.