Yes, the magnetic field inside a long solenoid is generally uniform.
The magnetic field B inside a long solenoid is independent of the distance from the center of the solenoid. It is also independent of the material inside the solenoid and the current passing through it.
The electric field inside an infinitely long cylindrical conductor with radius r and uniform surface charge density is zero.
To make a long story short I wanna mention the name of several methods to make uniform dc magnetic fields: Using the space inside a solenoid Using the Helmholtz coil Using the Maxwell coil as all of these configurations take benefits of the phenomena in which current produces a magnetic field, the amplitude of the magnetic field would be easily controlled by control upon the current passes the loops of windings.
A solenoid, which is a long coil of wire, produces a magnetic field similar to that of a bar magnet when a current passes through it. The magnetic field produced by a solenoid is confined within the coil and has north and south poles along its axis.
The electric field around a very long uniformly charged cylinder is uniform and points radially outward from the cylinder.
The magnetic field B inside a long solenoid is independent of the distance from the center of the solenoid. It is also independent of the material inside the solenoid and the current passing through it.
The electric field inside an infinitely long cylindrical conductor with radius r and uniform surface charge density is zero.
When an electron moves along the axis of a long straight solenoid carrying a current I, the magnetic field inside the solenoid is uniform and directed along the axis. According to the Lorentz force law, the force acting on a charged particle moving in a magnetic field is given by ( F = q(\mathbf{V} \times \mathbf{B}) ), where ( \mathbf{V} ) is the velocity of the electron and ( \mathbf{B} ) is the magnetic field. Since the velocity of the electron is parallel to the magnetic field in the solenoid, the cross product ( \mathbf{V} \times \mathbf{B} ) equals zero. Thus, the force acting on the electron due to the magnetic field of the solenoid is zero.
No, just close. A solenoid provides a magnetic field that is approximately uniform near its center. (One should compare this to a Helmholtz coil.) The keyword is "approximate" and one really understand the assertion of uniformity to mean nearly uniform near the center. To say that it is a good approximation would mean that small deviations from the center produce variations that are small. Specifically, one would expect variations that deviate from a constant magnetic field to be no worse than quadratic with distance and that is actually correct. (It may even be fourth order but that requires a calculation to check.) To give another rough idea of the field variation, it is simple to prove that for a long solenoid, the field at the end is half of the field at the center, so it does vary by a factor of two along its length.
no
The magnetic field outside a solenoid is nearly zero due to the cancellation of magnetic fields generated by individual current-carrying loops within the solenoid. These loops produce magnetic fields that point in opposite directions, resulting in a net magnetic field of zero outside the solenoid. Additionally, the magnetic field lines tend to stay within the solenoid due to the high permeability of the material surrounding the coils, further reducing the magnetic field outside the solenoid to negligible levels.
To make a long story short I wanna mention the name of several methods to make uniform dc magnetic fields: Using the space inside a solenoid Using the Helmholtz coil Using the Maxwell coil as all of these configurations take benefits of the phenomena in which current produces a magnetic field, the amplitude of the magnetic field would be easily controlled by control upon the current passes the loops of windings.
A solenoid, which is a long coil of wire, produces a magnetic field similar to that of a bar magnet when a current passes through it. The magnetic field produced by a solenoid is confined within the coil and has north and south poles along its axis.
The electric field around a very long uniformly charged cylinder is uniform and points radially outward from the cylinder.
Inside the trans. It is the part on the valve body with the long wiring pigtail attached.
Inside the transmission, on the valve body. It is the one with the long wiring pigtail on it.
A solenoid is a long cylindrical coil of wire consisting of a large number of turns bound together very tightly. A solenoid is usually used to produce a magnetic field to pull the armature of a relay, causing electrical contacts in the relay to open and/or close switching current flow.