Dipole moment is a term that describes the tendency of a charged particle to move in a direction other than its own. This is a major part of the electric force and is responsible for the superluminescence of stars and galaxies. The Dipole Moment is responsible for the movement of the magnetic field that surrounds the Earth and the sun.
There aren’t many people in history who have used this term, but it would probably sound a little bit more like a term that describes the effect of a charged particle on a target.
You know, this is the term we used when we were talking about in the previous chapter. It’s a little more complex than that, but it’s a pretty big deal.
Dipole Moment. A dipole is a point in space where two magnetic moments cancel out. This is why magnets tend to have a dipole moment. This is what is taking place when a charged particle (such as an electron) collides with a target. This means that the charged particle moves away from its original point of origin, but the magnetic field created by the target attracts the charged particle in the opposite direction.
Electrons are negatively charged particles. A large negative charge exists at the point of impact. Colliding electron and target particle have a net charge of zero. That, in turn, means the net charge of the target is positive.
Dipole moment, like the dipole moment of the electron, is a property of a particle. The dipole moment is the property of an electron. Since electrons are positively charged, the dipole moment is positive. Electrons are the only particles that create a net electric charge in a closed space. The dipole moment is a property of a particle. In a closed space, the dipole moment is zero.
So, to recap, I’m not a particle physicist. Electrons are positively charged and the dipole moment is positive. I’m not a particle physicist either.
So to sum up, an electron’s dipole moment is positive.
To me, it also shows that dipoles have a non-intuitive way of interacting with other dipoles. For example, a positive charge would repel a negative charge, and a negative charge would attract a positive charge. In other words, the dipole moment is positive.
The dipole moment is the dipole’s contribution to the magnetic field. A positively charged dipole has a magnetic dipole moment equal to its positive charge, so the dipole has a magnetic dipole moment of 1.