Solving Magnet Problems: Minimum Magnetic Field for Horizontal Northward Motion

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To maintain a particle with mass m and negative charge -q moving horizontally northward in Earth's gravitational field, a minimum magnetic field B is required. The particle's initial velocity is v, and the gravitational force mg must be balanced by the magnetic force exerted on the current I, which is derived from the charge's motion. The relationship is established as mg = IsB, leading to the formula B = mg/(qv) for the magnetic field's magnitude. The direction of the magnetic field can be determined using the right-hand rule, with adjustments for the negative charge. This analysis effectively clarifies the conditions necessary for the particle's motion in a magnetic field.
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I am having too hard of a time with such a simple magnet equation that I am starting to loose it.

A particle with a mass of m carries a negative charge of - q. The particle is given an initial horizontal velocity that is due north and has a magnitude of v.

What is the magnitude of the minimum magnetic field that will keep the particle moving in the Earth's gravitational field in the same horizontal, northward direction? Use g for the acceleration due to gravity.
 
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Let the charge be traveling a distance s in time t. Visualise this as a thin wire carrying current in a magnetic and gravitational field.

The current carried by the charge is I = \frac{dq}{dt} = \frac{qv}{s}

A magnetic field directed perpendicular to the motion of charge will exert a force on the wire given by F = IsB. This force has to balance the weight of the "wire" = mg.

Hence mg = IsB = \frac{qv}{s}(s)(B) = qvB

Therefore B = \frac{mg}{qv}.

That's the magnitude. For the direction, use the right hand rule, but remember that the current in the right hand rule is conventional current, so you need to reverse the direction for negatively charged carriers.
 
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Thank you, for putting it clearly.
 
Sure. :smile:
 

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