The magnetic fields are made a lot of in the solar wind. The solar wind hits the earth from the sun when it is close to the surface of the sun. This is why the sun is a bright orb that gives off light. These fields are also formed from the dust and debris that are carried away by the solar wind.
This is one of the main causes of solar flares, which are powerful explosions that can cause the earth to erupt into a shower of geysers. There is also a more subtle effect of these flares, which is that their cause is traced to magnetic fields.
In most cases, we can calculate the strength of the magnetic field from the speed of the solar wind. But the magnetic field of the sun is not continuous. It’s broken into a series of magnetic loops. When a solar flare occurs, some of these magnetic field lines start to twist. This causes the magnetic field to bend. This is what gives solar flares their spiky appearance.
As it turns out, it’s not just the strength of the magnetic field that is important, but its shape. The solar flares we see on the sun are typically geysers of plasma. This plasma is plasma that is ejected when a magnetic field changes. In the case of a solar flare, it’s ejected when two or more magnetic field lines twist. When two twisted field lines collide, they become one.
These lines bend due to the solar wind. That means that the solar wind will flow around the sun. As the solar winds pass toward the earth, the magnetic fields around the sun will also bend. This is what causes solar flares to spurt out.
Scientists were able to use this bent solar wind to measure magnetic fields on the sun. In this video, you can see how they used a laser to create a magnetic field on to a foil for the sun. They then used a laser to measure the change in the magnetic field of the foil. The scientists then used a computer to determine how fast the bend in the foil was. This was done at the University of Hawaii.
The video has been viewed over 10 million times and the scientists have no idea what caused the bend. I can’t imagine what else the people at the University could have done better.
The video is over 10 minutes long, but you can watch it below.
The video is an example of what I was talking about earlier. The only way to get a good idea of what the field is like is to watch it from a distance, and then measure the change in the field at various angles. This can be done with just a couple measurements, but a good measurement requires a large number of samples.
The video is not the only example of the solar system’s magnetosphere. A number of other solar sources can be used to measure the solar magnetic field. I found this study which used both the sun and the earth. Using this method of determining the solar magnetic field we were able to determine the magnetic field of the earth and the sun to within 3 % accuracy.