Grade 12 Electromagnetic Problem

[Dan17]

A wire, whose linear mass density is 150g/m, carries a current of 40A (supplied by a flexible negligible weight). This wire lies parallel to, and on top of, another horizontal wire on a table. What current must flow through the bottom wire in order to repel and support the top wire at a height of 4.0 cm above it? The top wire is held in place by frictionless guide plates.

Thanks,

...Dan

 

[bobp718]

The field due to a wire is

B=\frac{\mu_{0}I}{2\pi r}

and the direction can be determined by use of the right hand rule. The force associated with these fields is given by the lorentz force law

F_{mag}=qvB

when the field and the motion are perpendicular. Let's look at this another way... let's say that the lorentz force law read

F_{mag}=\frac{qLB}{\Delta t}

we can then move that \Delta t over to q and get somthing that looks like this

F_{mag}=ILB=\frac{\mu_{0}I_{1}I_{2}}{2\pi r}L

Utilizing Newton's Second law, in order for one wire to repel and support the other the forces must be equal.

0=F_{mag}-F_{grav}

so we set the forces equal. (\mu and \mu_{0} are not related in any kind of way,\mu is the linear mass density)

\mu gL=\frac{\mu_{0}I_{1}I_{2}}{2\pi r}L

and we get a result that is only dependant on the second current

I_{2}=\frac{\mu 2\pi rg}{\mu_{0}I_{1}}

Before you start putting numbers in make sure you understand what I have said here. And remember to give the current the proper polarity as indicated by the right hand rule.

 

[Dan17]

Thanks for the help