It just does. Electricity and magnetism turns out to be two sides of the same force, called electromagnetism, and either easily converts to the other.
When you change the electric current through a material (or accelerate a charged particle), you get a magnetic field as a side effect. We use this to make electromagnets.
When you change a magnetic field, you get an electric field as a side effect. We use this to make electricity generators.
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An accelerated charge produces a changing electric field, which in turn creates a magnetic field according to Maxwell's equations. This magnetic field encircles the path of the charge, resulting in the production of a magnetic field around it.
When electric charge accelerates it produces electric field and magnetic field perpendicular to each other and since the charge is accelerating the fields produced are perpendicular to the direction of charge accelerating and this is nothing but we name electromagnetic waves.
The vibration of electrically charged particles produces a type of energy known as electromagnetic radiation.
Bar magnets display a characteristic type of charge called magnetic charge. These charges create a magnetic field around the magnet and can interact with other magnets or magnetic materials in their vicinity.
A magnet affects only moving charges due to their magnetic field alignment. Stationary charge particles do not produce a magnetic field of their own and do not interact with magnetic fields in the same way.
Electrical charge can be produced from an electromagnet. This is a core i.e. iron wrapped in a wire coil. A magnetic device then passing by can cause an electrical charge to be produced, typically AC (alternating current).
No, a stationary electron placed in a stationary magnetic field would not move due to the magnetic field alone. The force experienced by a charged particle in a magnetic field is perpendicular to both the magnetic field and the velocity of the particle. In this case, since the electron is stationary, there is no component of its velocity perpendicular to the magnetic field for the magnetic force to act upon.
When a charge is stationary then an electric field exists. If that charge moves uniformly in space then magnetic field arises around the direction of movement of that charge. If the same charge gets accelerated then electromagnetic disturbance is produced in the space. So any charge oscillating or moving in a curved path would produce electromagnetic disturbance. Such a disturbance is known as electromagnetic waves.
No, a stationary charge particle cannot be accelerated in a magnetic field. In order to be affected by a magnetic field, the charged particle must be moving.
A moving electric charge creates electric and magnetic fields around it. The electric field exerts a force on other charges, while the magnetic field causes the charge to experience a force in the presence of magnetic fields.
Moving electric charges create a magnetic field. When charged particles such as electrons move, they generate a magnetic field around them. The relationship between electricity and magnetism is described by Maxwell's equations in electromagnetism.
Yes, a moving charge can produce a magnetic field as it generates a magnetic field due to its motion. This phenomenon is described by Ampere's law in electromagnetism.
It produces a magnetic field.
A charge moving perpendicular to a magnetic field experiences a force that is perpendicular to both the charge's velocity and the magnetic field direction. This force causes the charge to move in a circular path around the field lines, with the radius of the circle determined by the charge's speed and the strength of the magnetic field. This phenomenon is known as magnetic deflection.
The vibration of electrically charged particles produces a type of energy known as electromagnetic radiation.
A moving electric charge creates a magnetic field around it. This magnetic field interacts with other nearby magnetic fields and forces, leading to various electromagnetic effects such as electromagnetic induction or magnetic attraction/repulsion.
Electromagnetic oscillators are devices that generate and produce electromagnetic oscillations or waves, typically through the interaction of an electric field and a magnetic field. These oscillators are used in various applications, such as radio communication systems, radar systems, and microwave devices. Examples include oscillators like the LC circuit and magnetron.
Bar magnets display a characteristic type of charge called magnetic charge. These charges create a magnetic field around the magnet and can interact with other magnets or magnetic materials in their vicinity.
No the battery don't have a magnetic charge.