The gravitational potential energy of a gas cloud is proportional to its mass and inversely proportional to its density. In other words, a gas cloud of low mass, low density will have a small gravitational potential energy, while a gas cloud of high mass and high density will have very little gravitational potential energy.
So what you’re seeing in this video is a hypothetical scenario using our gas clouds to show how a relatively small gas cloud shrunk down to the size of a solar system, while maintaining a constant gravitational potential energy.
The video below is a fun example of this. Imagine you lived in a gas cloud the size of a solar system. Now, imagine you have a gas cloud that is twice the size of a solar system, but is still a gas cloud. This gas cloud would have a gravitational potential energy of zero, but its density would be twice that of the solar system.
This is the first time we’ve shown this concept with a video. While the video can be fun to watch, it gets to the heart of what we’re trying to accomplish with this video. Basically, the video shows how gas clouds shrink and shrink, but still have a gravitational potential energy that remains the same. It’s like we’re constantly shrinking our gas clouds, but also creating a gravitational potential energy that keeps them from collapsing.
So we see in the video that gas clouds shrink because they have a potential energy of zero, but we keep them the same size because our gravitational potential energy keeps them from collapsing. This is just one example of how the gas clouds are constantly shrinking and also creating a gravitational potential energy that keeps them from collapsing. Because the gas cloud is constantly shrinking, it creates a gravitational potential energy that keeps it from collapsing.
There is some debate in the science community because the gas clouds that we are talking about, are very different from the ones we are seeing in the video. Gas clouds are usually made up of hydrogen, helium, and other small particles. Most gas clouds are very dense, so they create a gravitational potential energy that keeps them from collapsing. But there are gas clouds that are very low density, where the gravitational potential energy has been released and it has just been thrown by the expanding gas cloud.
In the video above, the gas cloud in the sky is actually the one moving as a singularity. It’s not even a cloud, it’s just a tiny cloud of gas. The video above also shows that under its own gravity, the gas cloud is just getting hotter and hotter. I think this is what will cause the gas cloud to shrink in size in the final game. The gas cloud will move closer to our moon and closer to the sun, and it will get warm.
I think this will cause the gas cloud to shrink in size, which in turn, will cause the gravitational potential energy to be released and it will cause the gas cloud’s gravitational potential energy to be thrown out into space and it will cause the gas cloud’s gravitational potential energy to be thrown out into space.
I think the gravity-related potential energy from the gas clouds will be thrown out into space and it will cause the gas clouds gravitational potential energy to be thrown out into space.
