Yes, typically about 2/3 of the speed of light in a vacuum - that is, about 200,000 km/sec. Note that the drift speed of the electrons is only a fraction of a millimeter per second, and the random speed of electrons is faster, but still much slower than the speed of the CURRENT.
Yes, typically about 2/3 of the speed of light in a vacuum - that is, about 200,000 km/sec. Note that the drift speed of the electrons is only a fraction of a millimeter per second, and the random speed of electrons is faster, but still much slower than the speed of the CURRENT.
Yes, typically about 2/3 of the speed of light in a vacuum - that is, about 200,000 km/sec. Note that the drift speed of the electrons is only a fraction of a millimeter per second, and the random speed of electrons is faster, but still much slower than the speed of the CURRENT.
Yes, typically about 2/3 of the speed of light in a vacuum - that is, about 200,000 km/sec. Note that the drift speed of the electrons is only a fraction of a millimeter per second, and the random speed of electrons is faster, but still much slower than the speed of the CURRENT.
Charge moves in response to an electric field. When a force is exerted on a charged particle by an electric field, the particle will accelerate and move in the direction of the force. This movement of charge is the basis for electric currents and the functioning of electronic devices.
No, permanent magnets are not produced by electric currents. They are made from materials that are magnetized and retain their magnetic properties without the need for external electric currents.
The letter "I" is typically used to represent electric currents in equations.
An electric field exerts a force on charged particles, causing them to move. This movement can result in the acceleration of charged particles, which can lead to the generation of electric currents or the polarization of materials. Additionally, electric fields can store energy in the form of electric potential energy.
The unit that measures electric currents is the ampere (A). One ampere is equivalent to the flow of one coulomb of charge per second.
because when the ions can move around freely, they can conduct electricity better
They move just like snake do. They use small currents in the water to push against to propel themselves forward. Often, these currents are undetectable. Also, if there are no currents available, they use small "fins" to push against the water to move forward.
coils answer for aplus chris Crosby class of 2013
An electric motor cannot move. It can power something else that does move but you fail to list what it is installed in.
Charge moves in response to an electric field. When a force is exerted on a charged particle by an electric field, the particle will accelerate and move in the direction of the force. This movement of charge is the basis for electric currents and the functioning of electronic devices.
Warm currents move from the equator to the poles, and the cold currents move from the poles to the equator. :D
No, permanent magnets are not produced by electric currents. They are made from materials that are magnetized and retain their magnetic properties without the need for external electric currents.
Convection currents move in the Mantle.
The letter "I" is typically used to represent electric currents in equations.
Convection currents move in upward direction
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Yes