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Force on a Moving Charge A charged particle experiences a force when moving at a non-zero angle with respect to a magnetic field. The force on the charge.

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Presentation on theme: "Force on a Moving Charge A charged particle experiences a force when moving at a non-zero angle with respect to a magnetic field. The force on the charge."— Presentation transcript:

1 Force on a Moving Charge A charged particle experiences a force when moving at a non-zero angle with respect to a magnetic field. The force on the charge is greatest when It moves perpendicular to the magnetic field. F=qvB sinθ q = the amount of charge in motion in the magnetic field v = the velocity the charge in the magnetic field B = the magnetic field strength θ = the angle between the velocity direction and magnetic field Direction conventions: x: into the page (-z): out of the page (+z) x x x Field lines out of the page B Field lines into the page B v velocity out of the page Fx force into the page The force, charge velocity direction, and magnetic field direction are all perpendicular to each other. There is no force on a charge that moves parallel to a magnetic field.

2 First Right Hand Rule velocity force magnetic field Used to determine the velocity direction, force direction, and magnetic field direction for a charge in motion in a magnetic field. The right hand rule is used for positive charges.

3 Example Problem A proton moves at 3.0x10 5 m/s in the positive-x direction while a 4.5 T magnetic field acts in the negative-y direction. What is the magnitude and direction of the force exerted on the proton? F=qvBsinθ=(1.6x10-19C)(3.0x10 5 m/s)(4.5 T) sin90°=2.2x10 -13 N Use the first right hand rule to determine the force direction on the charge. -z direction

4 What is the resulting motion of a charge in a magnetic field? v F - What is the direction of the magnetic field surrounding the charge?

5 Force on wire in a magnetic field +++++ + + I A current in a wire constitutes charges in motion. F = qvBsinθ =q(L/t)B sinθ = (q/t)LBsinθ = BILsinθ L F=BILsinθ F=force on the wire from the external magnetic field B = The external magnetic field that surrounds the wire I = current in the wire L=length of wire in the magnetic field θ = angle between the current direction and magnetic field. The direction of the magnetic field can be determined by the right hand rule with the current I, replacing the velocity direction.

6 Example problem A wire length carries 6.5 A of current along the positive-x axis while in a magnetic field of 7.0 T directed towards the positve-z axis. A length of 18 cm of wire is exposed to the magnetic field. What is the magnitude and direction of the force on the wire? F=BILsinθ = (7.0 T)(6.5 A)(.18m)sin 90° F=8.2 N Use the right hand rule to determine the direction of the force. Force direction: -y

7 An Applications of Force on a Wire – Simple Internal Diagram of an Electric Motor Motor – a device which converts energy to mechanical motion Metal brushes inside ring SN II x

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