Gravity field Magnetic field Temperature field
The electric field produced by a charged particle, which exerts a force on other charged particles within its influence. The electric field between the plates of a capacitor, which stores energy in the form of electric potential. The electric field surrounding a lightning bolt, which can be extremely intense and dangerous.
Gravitational force field, electric force field, magnetic force field.
The net electric field inside a dielectric decreases due to polarization. The external electric field polarizes the dielectric and an electric field is produced due to this polarization. This internal electric field will be opposite to the external electric field and therefore the net electric field inside the dielectric will be less.
for apex its: a quantum field, a gravitational field
Gravity field Magnetic field Temperature field
The electric field produced by a charged particle, which exerts a force on other charged particles within its influence. The electric field between the plates of a capacitor, which stores energy in the form of electric potential. The electric field surrounding a lightning bolt, which can be extremely intense and dangerous.
Gravitational force field, electric force field, magnetic force field.
The net electric field inside a dielectric decreases due to polarization. The external electric field polarizes the dielectric and an electric field is produced due to this polarization. This internal electric field will be opposite to the external electric field and therefore the net electric field inside the dielectric will be less.
for apex its: a quantum field, a gravitational field
Three examples of vectors are force (e.g., push or pull), velocity (e.g., speed and direction of an object's motion), and electric field (e.g., direction and magnitude of an electric force on a charged particle).
It's the electric field.
Yes, an electric field can exist without a magnetic field. Electric fields are produced by electric charges, while magnetic fields are produced by moving electric charges. So, in situations where there are stationary charges or no current flow, only an electric field is present.
Any quantity for which a direction is relevant. Examples include displacement, velocity, acceleration, force, electric field, magnetic field, and many more.
Electric field intensity is related to electric potential by the equation E = -∇V, where E is the electric field intensity and V is the electric potential. This means that the electric field points in the direction of steepest decrease of the electric potential. In other words, the electric field intensity is the negative gradient of the electric potential.
Electric field lines represent the direction of the electric field at any point in space. If there were sudden breaks in the field lines, it would imply sudden changes in the electric field strength, which is not physically possible. The electric field must vary continuously and smoothly in space.
Electric field lines represent the continuous flow of electric field from one point to another. If there were a sudden break in the electric field line, it would imply a sudden discontinuity in the electric field strength, which is not physically possible. This is because electric field lines are a visual representation of the direction and strength of the electric field, which must be continuous to maintain the conservation of electric field flux.