The magnetic field of a moving charge affects its surrounding environment by creating a magnetic field that can interact with other moving charges or magnetic materials. This interaction can result in forces being exerted on the charges or materials, causing them to move or change direction.
it depends on what kind of charge it is if its a positive charge then protons are surrounding it if it is a negative charge then electrons are surrounding it does that make sense?
The presence of a charged wire creates an electric field in its surrounding environment. The electric field is stronger closer to the wire and weaker farther away. The direction of the electric field lines depends on the charge of the wire.
The factors that affect the magnitude of magnetic force include the strength of the magnetic field, the charge of the moving particle or current-carrying wire, and the angle between the magnetic field and the direction of motion of the particle. The distance between the magnet and the object also affects the strength of the magnetic force.
For magnetic forces, factors that affect strength include the magnitude of the magnetic field, the charge of the particles involved, and the relative velocity between the charged particles. For electric forces, factors include the magnitude of the charge on the particles involved, the distance between the charges, and the medium through which the charges interact.
The strength of electric forces is influenced by the charge of the objects involved and the distance between them (Coulomb's law). For magnetic forces, the strength is determined by the magnitude of the magnetic field, the charge of the moving particle, and the velocity of the particle (Lorentz force law).
it depends on what kind of charge it is if its a positive charge then protons are surrounding it if it is a negative charge then electrons are surrounding it does that make sense?
The presence of a charged wire creates an electric field in its surrounding environment. The electric field is stronger closer to the wire and weaker farther away. The direction of the electric field lines depends on the charge of the wire.
A black hole can have an electric charge if it swallows electrically charged objects, but no objects that we know of have magnetic charge. Magnets always have both a north pole and a south pole; there is no evidence that one can exist alone. A lone north or south pole would be called a magnetic monopole, and would have magnetic charge. If we discovered a magnetic monopole and fed it to a black hole then the black hole would gain the magnetic charge.
No the battery don't have a magnetic charge.
Basically the environment, resources, the equipment, the people in charge of the care.
The factors that affect the magnitude of magnetic force include the strength of the magnetic field, the charge of the moving particle or current-carrying wire, and the angle between the magnetic field and the direction of motion of the particle. The distance between the magnet and the object also affects the strength of the magnetic force.
For magnetic forces, factors that affect strength include the magnitude of the magnetic field, the charge of the particles involved, and the relative velocity between the charged particles. For electric forces, factors include the magnitude of the charge on the particles involved, the distance between the charges, and the medium through which the charges interact.
Basically the environment, resources, the equipment, the people in charge of the care.
The strength of electric forces is influenced by the charge of the objects involved and the distance between them (Coulomb's law). For magnetic forces, the strength is determined by the magnitude of the magnetic field, the charge of the moving particle, and the velocity of the particle (Lorentz force law).
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.
An electric field can created by a presence of a charge particle such as electron or proton. While a magnetic fieldis created due the relative motion of a charge particle with repeat to a stationary observer, motion of the charge particle.
Electric charge produces an electric field by just sitting there. It doesn't have to move. If it moves, it produces a magnetic field. It doesn't matter how the motion would be described.