Michael Faraday
Alessandro Volto had several contributions in the field of electricity. He invented the electric cell, the battery, the Voltaic pile and methane.
Chance doesn't enter into the equation. Preparation and planning is a better way
THOMAS MOORE is a writer. he is in no way related to inventions in the field of science.
A generator moves a coil of wire through a magnetic field and that induces a current in the coil .
Electric field intensity is related to electric potential by the equation E = -dV/dx, where E is the electric field intensity, V is the electric potential, and x is the distance in the direction of the field. Essentially, the electric field points in the direction of decreasing potential, and the magnitude of the field is related to the rate at which the potential changes.
Electrostatic field surrounds a stationary charge. A moving charge has magnetic and electric field surrounding it. But since the mag. field at a point due to the moving charge keeps changing, there is also an induced electric field. this ind. electric field in turn induces a magnetic field. and this goes on in a cycle. (Maxwell equation)
Gauss's law: Electric charges produce an electric field. Gauss's law for magnetism: There are no magnetic monopoles. Faraday's law: Time-varying magnetic fields produce an electric field. Ampère's law: Steady currents and time-varying electric fields produce a magnetic field.
Force can be found using the equation F=qE, where q is the given charge 2C and E is the unknown electric field. Force is given as 60 N which modifies the equation to E=F/q. Substituting the values we get E=60/2= 30N/C which is the electric field at the location of the charge.
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
The electric field at a point in space is the magnitude and direction of the force that would act on a small test charge if it were located at that point.
An electric field can exist even without the presence of a magnetic field. An example of this is a stationary electric field.
The electric field gets stronger as you get closer to an electric charge.
It's the electric field.
electric field lines represents electric field at that point but if it has break somewhere then it signifies the absence of electric field and it is not possible.....
The lines in each diagram represent an electric field. The stronger the field, the close together the lines are.