Answer:
[tex]I=9.6*10^{-8}A[/tex]
Explanation:
We first calculate the change in magnetic flux ([tex]\Phi_B[/tex]) due to the change in the magnitude of magnetic field (B), since que current (I) in the solenoid changes. B and [tex]\Phi_B[/tex] are given by:
[tex]\Phi_B=ABcos\theta\\\frac{\Delta \Phi_B}{\Delta t}=A\frac{\Delta B}{\Delta t}cos\theta(1)\\B=n\mu_0I\\\frac{\Delta B}{\Delta t}=N\mu_0\frac{\Delta I}{\Delta t}(2)[/tex]
In this case, the magnetic field is always perpendicular to the square loop. We replace (2) in (1):
[tex]\frac{\Delta \Phi_B}{\Delta t}=An\mu_0\frac{\Delta I}{\Delta t}cos(90^\circ)[/tex]
According to Faraday's law:
[tex]\epsilon=-\frac{\Delta \Phi_B}{\Delta t}\\\epsilon=-An\mu_0\frac{\Delta I}{\Delta t}\\[/tex]
The minus sign means that the resulting current will have a direction such that the induced magnetic field will oppose the original change in flux. Here, n is the number of turns per unit length and A is the solenoid area
[tex]\epsilon=(\pi r^2)(\frac{N}{L})\mu_0\frac{\Delta I}{\Delta t}\\\epsilon=\pi(0.025m)^2(\frac{500}{0.3m})(4\pi*10^{-7}\frac{T*m}{A})(0.7\frac{A}{s})\\\epsilon=2.88*10^{-6}V[/tex]
Recall that [tex]\epsilon[/tex] is an induced voltage. We use the Ohm's law to calculate the current:
[tex]V=IR\\I=\frac{V}{R}\\I=\frac{2.88*10^{-6}V}{30\Omega}\\I=9.6*10^{-8}A[/tex]
