A theory of how the sun creates heat: when sunlight interacts with something, it makes it vibrate. At sea level, all the heavy molecules are, like O2. The heavier a molecule is, the more energy it produces once it vibrates, which we experienced as heat. 1000 meters over sea level, the air is thinner, less heavy molecules are here, producing less energy ones sunlight interacts with it, making it colder the higher up in the air you go.
Yes. The closer you are to the sun, at sea level, the hotter it gets. The further away you are from the sun at sea level, the colder it gets. In December, the Arctic experience little to no sun light, making water at sea level to freeze; in June, the Arctic experience 24 hours sunlight, making the ice at sea level to melt.
But it's closer to the sun, right?
A theory of how the sun creates heat: when sunlight interacts with something, it makes it vibrate. At sea level, all the heavy molecules are, like O2. The heavier a molecule is, the more energy it produces once it vibrates, which we experienced as heat. 1000 meters over sea level, the air is thinner, less heavy molecules are here, producing less energy ones sunlight interacts with it, making it colder the higher up in the air you go.
So take everything you just said here and apply it to observed reality about the planet.
Yes. The closer you are to the sun, at sea level, the hotter it gets. The further away you are from the sun at sea level, the colder it gets. In December, the Arctic experience little to no sun light, making water at sea level to freeze; in June, the Arctic experience 24 hours sunlight, making the ice at sea level to melt.
It's strange that you can put that together but not apply it to what you said 6 replies ago.