Isaac0427
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You can have regions in space where there are no magnetic materials or currents, and for these regions, in the steady state, the magnetic field ## B ## will be conservative/can be considered conservative, and can be written as ## B=-\nabla \Omega_m ## where ## \Omega_m ## is a magnetic potential function. It really is better physics to be able to speak in general terms about the magnetic field ## B ##, instead of finding cases where it can be considered conservative. editing...You might ask, what applications might this have? For a single electric charge, the force is proportional to the velocity, but for a magnetic dipole, or for a permanent magnet which is a conglomeration of magnetic dipoles, you can write ## U=-m \cdot B ## and you could compute the forces on the magnet in the magnetic field. Under certain conditions (e.g. fixed magnetic moments, i.e. where the magnetization ## M ## of the permanent magnet is not affected by the external field), conservative force laws may be applicable.Isaac0427 said:Thank you for the helpful answers, but once again I have two completely opposite answers. I'd ordinarily agree with @Charles Link but I question that because of what people like @Cutter Ketch say. The B field shouldn't fit any of the mathematical definitions unless there is no current, and you can't have a B field without a current, right (that could be wrong, so please correct me. I believe that the A potential has to do with current, and without an A potential you have no B field)? What's going on here. To be clear, I am not talking about the force, I am talking about B.
Ok, so what I am getting at is that B is nonconservative and the magnetic force is neither conservative nor nonconservative (it does not follow condition three but it does follow the others). Correct?Charles Link said:You can have regions in space where there are no magnetic materials or currents, and for these regions, in the steady state, the magnetic field ## B ## will be conservative/can be considered conservative, and can be written as ## B=-\nabla \Omega_m ## where ## \Omega_m ## is a magnetic potential function. It really is better physics to be able to speak in general terms about the magnetic field ## B ##, instead of finding cases where it can be considered conservative.
Please read the "edit" that I added to post #6. The force on a permanent magnet in a magnetic field can be written as an integral of such gradients(condition 3 in your OP) of ## U=-M \cdot B ## . In the way I just wrote it ## U ## is the magnetic energy per unit volume.Isaac0427 said:Ok, so what I am getting at is that B is nonconservative and the magnetic force is neither conservative nor nonconservative (it does not follow condition three but it does follow the others). Correct?
In general, with static magnetic fields, you will always have currents. If the region of interest lies outside these currents, and the object of interest consists of magnetic dipoles, then it would appear that you can have a conservative field and a conservative force. If the magnetic field induces additional (magnetic) dipoles in the material, I think you will find the field and forces are non-conservative and hysteresis losses will occur. ## \\ ## If you are looking at the effect of the magnetic field on charged particles, it is clearly non-conservative. The purpose of calling it conservative is to be able to write a potential function or similar expression like you do for a charged particle in an electric field where you can assign a voltage to a location and that voltage is independent of the path the particle took to get there. In traveling from one location to another the energy it acquires or loses can be computed from the potential function. A similar calculation applies for the gravitational potential.Isaac0427 said:In the case that the magnetic field is conservative, would the magnetic force also be conservative?
In the case that a current exists, would it be a reasonable convention to call the magnetic force nonconservative as it does not observe all three conditions?
EDIT-- Sorry, there were 2 typos in there.