Question

A long straight wire carries a current of 51.7 A. An electron, traveling at 7.43 × 10^7 m/s, is 5.76 cm from the wire.

What is the magnitude of the magnetic force on the electron if the electron velocity is directed (a) toward the wire, (b) parallel to the wire in the direction of the current, and (c) perpendicular to the two directions defined by (a) and (b)?

Answer 1

(a) 2.13*10^{-5} N

(b) 2.13*10^{-5} N

(c) 0 N

Step-by-step explanation:

the magnitude of the magnetic field generated by the wire is:

`(\mu_0I)/(2\pi r)=((4\pi*10^(-7))(51.7A))/(2\pi(5.76*10^(-2)m))=1.79*10^(-4)T`

if we assume that the current is in the +y direction, B is in the +z direction.

(a) toward the wire, electron is in the -x direction. The angle between B and v is 90°. By using the following formula we obtain:

`F_1=qvBsin90\°=(1.6*10^(-19)C)(7.43*10^(7)(m)/(s))(1.79*10^(-4)T)=2.13*10^(-15)N`

(b) parallel to the wire, electron is in the +y direction. Again angle between B ans v is 90°.

`F_2=qvB=2.13*10^(-15)N`

(c) perpendicular to both previous directions, that is, +z or -z. In this case velocity vector is parallel to the magnetic field vector. Hence:

F3=0N

hope this helps!