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Why is a vibrating electric field an example of an electromagnetic wave?
A vibrating electric field produces a changing magnetic field, which then generates a changing electric field and so on, creating a self-propagating wave. This wave consists of oscillating electric and magnetic fields perpendicular to each other and to the direction of wave propagation, thus exhibiting the characteristics of an electromagnetic wave.
What consists of a vibrating electric field and a magnetic field?
An electromagnetic wave consists of a vibrating electric field and a magnetic field that oscillate in perpendicular directions to each other and propagate through space. These fields are generated by the movement of charged particles and carry energy and information.
When a blank wave that is produced by a vibrating electric charge is an electromagnetic wave?
When a vibrating electric charge produces a changing electric field, it in turn generates a changing magnetic field, leading to the creation of an electromagnetic wave. This wave consists of oscillating electric and magnetic fields that propagate through space at the speed of light.
How does a vibrating electric charge produce an electromagnetic wave?
When an electric charge vibrates, it creates changing electric and magnetic fields. These changing fields propagate through space, creating electromagnetic waves. The oscillating electric field produces a magnetic field, and the changing magnetic field then produces an electric field, thus creating a self-sustaining wave.
What is the relationship between electromagnetic waves and vibrations?
Electromagnetic waves are created by vibrating electric charges. When an electric charge oscillates, it creates a changing electric field which in turn generates a changing magnetic field. This interplay of changing electric and magnetic fields propagates through space as electromagnetic waves.
What causes a vibrating magnetic field?
A vibrating magnetic field can be caused by alternating current flowing through a conductor, which generates a changing magnetic field around the conductor. This changing magnetic field can induce a current in nearby conductors, causing them to vibrate as well. Other sources of vibrating magnetic fields can include electromagnetic radiation and electrical motors.
What is a magnetic field will be produced at some point in space if the electric field at the point?
As far as the electric field is stationary then no magnetic field. But when electric field is moving at a uniform speed then a magnetic field will be produced. This is what we call Lorentz magnetic field.
Which of the following are created by an arrangement of electric charge or a current?
for apex its: a quantum field, a gravitational field
How does an electromagnet utilize the interaction of electric and magnetic fields to generate a magnetic field when an electric current passes through it?
An electromagnet uses the interaction of electric and magnetic fields to create a magnetic field when an electric current flows through it. The electric current produces a magnetic field around the wire, and this field interacts with the magnetic field of the material inside the coil, strengthening the overall magnetic field.
Can an electric field exist without a magnetic 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.
Can a changing magnetic field produce a steady electric field?
Yes, a changing magnetic field can induce a steady electric field. This is described by Faraday's law of electromagnetic induction, where a changing magnetic field creates an electric field in the surrounding space.
How light waves travell through no media?
James Clerk[sic] Maxwell was able to show that an electric field vibrating at a specific frequency would result in a magnetic field vibrating at exactly that same frequency, and that the latter magnetic field would result in an electric field vibrating at the same frequency -- ad infinitem. He was also able to show that this continual vibration would travel away from its starting point at the speed of light -- thus showing that light, at its basic nature, is a vibrating EM field. Experiments showed that pretty much all predictions based on Maxwell's Equations did, indeed, occur -- such as this EM field travelling without any media needed.
