How Does the Right Hand Rule Determine Magnetic Force Directions?

AI Thread Summary
The right-hand rule is essential for determining the direction of magnetic forces on current loops and charged particles in magnetic fields. When applying it to a current loop, curling the fingers in the direction of the current flow indicates that the thumb points in the direction of the magnetic dipole moment. The torque experienced by the loop aligns this dipole moment with the external magnetic field. For charged particles, the force is calculated using the equation F = v × B, where v is the velocity and B is the magnetic field. Understanding how to apply the right-hand rule to cross products is crucial for accurately determining force directions.
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how do you find the direction of the magnetic force on a current loop..a loop that experiences a torque?
i know you use some kind of right hand rule but I am confused


also..the direction of a charged particle in a magnetic field


please helpppppp
 
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its the right hand rule, where ur fingers are in the direction of the current flow...im pretty sure
 
If you curl the fingers of your right hand in the direction the current flows around the loop, then your thumb points in the direction of the loop's magnetic dipole moment. The force on the loop will tend to align the dipole moment vector to be in the same direction as the external magnetic field the loop is sitting in.

The direction of the force on a charged particle in a magnetic field is:

\vec{F} = \vec{v} \times \vec{B}

where \vec{v}[\itex} is the velocity and \vec{B}[\itex] is the field.<br /> <br /> Do you know how to apply the right hand rule to cross products such as this one?
 

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