Answer:
[tex]B=\frac{\mu_o \epsilon_o R_o^2V_o}{2rd}cos(\omega t)[/tex]
Explanation:
By the information of the statement you have that the sinusoidal potential difference is given by:
[tex]V=V_osin(\omega t)=V_osin(2\pi ft)=150sin(2\pi (60)t)[/tex] (1)
In order to calculate the induced magnetic field in between the plates, you first take into account the following formula, which is the Ampere-Maxwell law:
[tex]\int B\cdot ds=\mu_o \epsilon_o\frac{d\Phi_E}{dt}+\mu_oI_c[/tex] (2)
B: induced magnetic field
μo: magnetic permeability of vacuum = 4π*10^-7 A/T
εo: dielectric permittivity of vacuum = 8.85*10^-12 C^2/Nm^2
Ic: conduction current
ФE: electric flux
There is no conduction current in between the plates, then Ic = 0A
Next, you calculate dФE/dt, as follow:
The electric field, and the electric flux, are:
[tex]E=\frac{V}{d}=\frac{V_osin(\omega t)}{d}\\\\\Phi_E=EA[/tex]
d: separation between plates = 5.0mm = 5.0*10^-3 m
A: area of the circular plates = [tex]\pi R_o^2[/tex]
Ro: radius of the circular capacitor = 3.0cm = 0.03m
Thus, dФE/dt is:
[tex]\frac{d\Phi_E}{dt}=\frac{d(EA)}{dt}=\pi R_o^2\frac{d}{dt}[\frac{V_osin(\omega t)}{d}]\\\\\frac{d\Phi_E}{dt}=\frac{\pi \omega R_o^2 V_o}{d}cos(\omega t)[/tex] (3)
The induced magnetic field is calculated by taking into account that the integral of the equation (2) is:
[tex]\int B \cdot ds=B\int ds=B(2\pi r)[/tex] (4)
Next, you replace the results of (3) and (4) into the equation (2) and you solve for B:
[tex]B(2\pi r)=\mu_o \epsilon_o (\frac{\pi \omega R_o^2 V_o}{d}cos(\omega t))\\\\B=\frac{\mu_o \epsilon_o R_o^2V_o}{2rd}cos(\omega t)[/tex] (5)
The last expression is de induced magnetic field in between the plates in terms of t and r
Another way of expressing the formula (5) is as follow:
[tex]B=B_ocos(\omega t)\\\\B_o=\frac{\mu_o \epsilon_o R_o^2V_o}{2rd}[/tex]
