Why does the higher the altitude, the lower the temperature? Isn t it closer to the sun?

Because the higher the altitude, the thinner the air is, and the less insulating the atmosphere is, the lower the temperature will be. In fact, the distance from the sun at high altitude is no different from that on the plane, the main thing is that the earth is really separated from the sun by a long distance, and the distance between the sea wave and the sun is even farther, but the temperature on the earth is really irrelevant to the distance from the sun at that point.

Because the earth is too far away from the sun, and the altitude is at most a few kilometers high, the heat felt does not change very much, but due to the influence of high altitude and atmospheric circulation, the temperature is low.

The atmosphere near the Earth's surface is the first to be heated by the sun, while the upper atmosphere only gains heat through thermal convection. So the higher you go, the lower the temperature.

The higher the altitude, the closer it is to the sun, why is the temperature getting lower and lower, and can humans reach the sun.

Why does the higher the altitude the lower the temperature? Considering it logically, doesn't it seem counterintuitive? Shouldn't it be the other way around?

After all, by moving to higher altitudes, you are approaching the sun, i.e. reducing the distance between yourself and the sun. By this reasoning, one should feel hotter in the hills and mountains, but it is well known that this does not happen. Why?

In short, the fiber shed fiber is due to atmospheric pressure. and Min.

First of all, you need to understand that the sun is very far from the earth; Therefore, moving to a higher altitude, there is no difference as the heat it provides has hardly changed. You have to be completely away from the Earth and closer to the Sun for the heat you experience to change significantly. Therefore, moving to the mountains will not bring you closer to the sun, at least in terms of heat.

Now, let's talk about the atmosphere. As you may already know, it is made up of a mixture of gases that surround the earth. Since the atmosphere surrounds the earth, i.e., it can be found almost anywhere on the earth, it also exerts a certain pressure on the surface of the earth, which is known as atmospheric pressure.

To put it simply, as long as the atmosphere is seen as a load that pushes the Earth downward, the downward pressure it pushes is what scientists call atmospheric pressure.

Now, let me tell you, this is no ordinary negative imitation load, because the Earth's atmosphere is a huge mixture of gases containing dust particles and weighs a lot. It's like having a little car on top of your head all the time. Theoretically, humanity and almost everything on Earth should be crushed by the weight of the atmosphere.

However, it is very interesting that the value of atmospheric pressure is different everywhere - it varies with altitude. That's why many things happen or don't happen at high altitudes.

As mentioned earlier, the atmosphere is simply a mixture of gases hovering over the Earth's surface. At sea level, the atmospheric pressure value is kilograms per square centimeter, but when you enter high altitudes, it starts to fall and almost exceeds this specific value.

Atmospheric pressure has this tendency because as the altitude increases, the number of air molecules decreases. Think of it this way: the higher you go up, the fewer molecules you push down from above.

This is why atmospheric pressure at high altitudes is much lower than at sea level.

Since the atmospheric pressure decreases with altitude, at high altitudes, the number of air molecules pressed on other molecules in the upper layer also decreases due to the thinning of atmospheric air. This leads to some kind of expansion as the molecules below have more room to wander. This makes them less likely to collide and ** to neighboring molecules, resulting in the kinetic energy of the molecules being distributed over a large area.

This lowers the average temperature of the system, i.e. the atmosphere at that altitude.

In contrast, in low-altitude areas, the air pressure is high, so there is not as much room for air molecules to move freely. They carry a lot of energy, and they collide with each other more frequently, resulting in an increase in the temperature of the system. That's why it's hotter at lower altitudes than in the mountains.

This law of physics applies everywhere, regardless of the mountains on the equator or the polar regions, regardless of the geographical location on the planet.

Because the higher the altitude, the farther away from the ground, the empty bench above is very thin, and the temperature is very low. The altitude is particularly high, and it is not particularly close to the sun. Therefore, the temperature is not particularly round, not high.

This is because the higher the altitude, the thinner the air, so the temperature is very low. It's not that the closer you get to the sun, the higher the temperature.