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Current carrying conductor will have magnetic lines around it. So when it is kept perpendicular to the magnetic field then the force would be maximum. The force depends on 1. magnitude of current 2. Magnetic field induction 3. Angle between the direction of current and magnetic field. Fleming's Left hand rule is used to find the direction of force acting on the rod
What force is acting? Gravity? Electricity? Magnetic repulsion? And what is the mass/charge on each sphere anyway?
yes, they can balanced if they r in opposite direction n have same magnitude.....
30 N to the right
Assuming this is a vacuum: Motion would occur only if there is no secondly force acting on the object with the same magnitude(strength) but has the opposite direction to the force you're acting upon this object.
It is a way of representing the magnetic force at a point in the field. The magnitude and direction of the vector represents the strength and the direction of the magnetic force acting on a charged particle in the field.
The answer simply depends on the environment that the electron is in. If the electron is in orbit around the nucleus of an atom then there will be a strong electromagnetic force acting on the electron towards the nucleus.
The proton behaves in the opposite direction of the electron in a magnetic field. bcz the magnetic field is due to motion of electrons in a conductor nd protons are +vely charged so it will be attracted by the magnetic field and so proton move in opposite direction to the electron i.e in anticlockwise direction
Ampere disconvered the relationship between the magnitude of an electric current and the force acting on a current-carrying conductor within a magnetic field. Thus, the unit of current, the ampere, was named in his honour.
A force of equal magnitude, acting in the opposite direction.
It is a vector with the same magnitude (size) but acting in the opposite direction.
Only if the wire is running perpendicular to a magnetic field.
The upward force acting on an object is the normal force. It is equal in magnitude, but opposite in direction to the object's weight.
Current carrying conductor will have magnetic lines around it. So when it is kept perpendicular to the magnetic field then the force would be maximum. The force depends on 1. magnitude of current 2. Magnetic field induction 3. Angle between the direction of current and magnetic field. Fleming's Left hand rule is used to find the direction of force acting on the rod
This is valid only for the attraction between a proton and an electron.
Magnitude is 315 N. Direction would be opposite the first force, so they cancel out and leave the body at rest.
What force is acting? Gravity? Electricity? Magnetic repulsion? And what is the mass/charge on each sphere anyway?