B is never in the direction of J.dorist84 said:Hello hello,
What is the b-field for a parallel plate capacitor if the current J was found to be in the z-direction? I am told it will be in the z-direction as well. How so?
Thanks so much!
dorist84 said:so I fear if i say too much, i run the risk of being mistaken for getting homework help here. eeeek. (im a newbie to the forums) truth be told...hw for this problem was due last week...it was a discussion with the ta and office hours that got this question rolling in my head. solutions have yet to be posted...so i'd love to keep posting if possible...
A magnetic field is a physical phenomenon that is produced by moving electric charges. It is a region in space where a magnetic force is exerted on other moving charges or on magnetic materials.
A parallel plate capacitor produces a magnetic field when an electric current flows through it. This is because the movement of electric charges creates a magnetic field around the conductor, which can be amplified by the parallel plates of the capacitor.
The direction of the magnetic field for a parallel plate capacitor depends on the direction of the electric current. According to the right-hand rule, the magnetic field will wrap around the conductor in a direction that is perpendicular to the direction of the electric current.
The distance between the parallel plates of a capacitor affects the strength of the magnetic field it produces. As the distance between the plates increases, the magnetic field becomes weaker. This is because the electric current has a longer distance to travel and therefore creates a weaker magnetic field.
Yes, there are several practical applications of a magnetic field for parallel plate capacitors. These include in electric motors, generators, and other electromagnetic devices. They are also used in medical imaging machines such as MRI scanners to produce detailed images of the inside of the human body.