Answer:
B = 38.2μT
Explanation:
By the Ampere's law you have that the magnetic field generated by a current, in a wire, is given by:
[tex]B=\frac{\mu_o I_r}{2\pi r}[/tex] (1)
μo: magnetic permeability of vacuum = 4π*10^-7 T/A
r: distance from the center of the cylinder, in which B is calculated
Ir: current for the distance r
In this case, you first calculate the current Ir, by using the following relation:
[tex]I_r=JA_r[/tex]
J: current density
Ar: cross sectional area for r in the hollow cylinder
Ar is given by [tex]A_r=\pi(r^2-R_1^2)[/tex]
The current density is given by the total area and the total current:
[tex]J=\frac{I_T}{A_T}=\frac{I_T}{\pi(R_2^2-R_1^2)}[/tex]
R2: outer radius = 26mm = 26*10^-3 m
R1: inner radius = 5 mm = 5*10^-3 m
IT: total current = 4 A
Then, the current in the wire for a distance r is:
[tex]I_r=JA_r=\frac{I_T}{\pi(R_2^2-R_1^2)}\pi(r^2-R_1^2)\\\\I_r=I_T\frac{r^2-R_1^2}{R_2^2-R_1^2}[/tex] (2)
You replace the last result of equation (2) into the equation (1):
[tex]B=\frac{\mu_oI_T}{2\pi r}(\frac{r^2-R_1^2}{R_2^2-R_1^2})[/tex]
Finally. you replace the values of all parameters:
[tex]B=\frac{(4\pi*10^{-7}T/A)(4A)}{2\PI (12*10^{-3}m)}(\frac{(12*10^{-3})^2-(5*10^{-3}m)^2}{(26*10^{-3}m)^2-(5*10^{-3}m)^2})\\\\B=3.82*10^{-5}T=38.2\mu T[/tex]
hence, the magnitude of the magnetic field at a point 12 mm from the center of the hollow cylinder, is 38.2μT
