# what is the speed of the electron in its orbit? Published

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Electron is the smallest subatomic particle in the universe. As a result, it has a very high speed. The speed of an electron is 1060 m/s. For that fact, we would not be able to reach our goal of “speed of light!” but we can calculate the speed of the electron in its orbit, which is around the speed of light.

The speed of electron in its orbit is around the speed of light, because the electron (or any other subatomic particle) is in its orbit at a very high speed. The speed of a subatomic particle is the product of its mass and its velocity. For example, the speed of a proton is around the speed of light. If you have a proton, then you can use your protons’ speed to calculate the speed of a proton’s orbit.

The electron orbits the nucleus, which has a mass of one-hundred-billion-billion-billion-billion-trillion metric tons. The speed of a proton orbit is around the speed of light. So let’s say you have a proton. If you also have a hydrogen nucleus, then you can use your proton’s speed to calculate the speed of a hydrogen atom’s orbit.

The speed of the electron is also a key factor in the physics of electricity and magnetism. In particular, the speed of the electron must be less than the speed of light (about 186,000 km/s). If the electron’s speed is greater than the speed of light, then it is effectively a photon.

This is the physics of light. The speed of the electron is also a key factor in the physics of magnetism, but if you have a magnet, the speed of the electron can actually be a factor in determining its magnetic field strength. This means that if you have a magnet, the speed of the electron is the speed of the photon in the magnet.

As the speed of the electron is so much greater than the speed of light, we can see that electrons also have a unique characteristic: A very high energy level. This is because of the way that electrons are made. Electrons are atoms, and we can see that in the fact that they have an energy level that is so much higher than that of other particles. This is actually the first time I’ve seen this statement in a video, but let me explain what this means. Click to comment