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Ning Zhu edited subsection_Direct_Fit_Method_We__.tex
over 8 years ago
Commit id: edb3ba5acbe2abffff08bd5dac74c7692182df90
deletions | additions
diff --git a/subsection_Direct_Fit_Method_We__.tex b/subsection_Direct_Fit_Method_We__.tex
index c79319f..4338a63 100644
--- a/subsection_Direct_Fit_Method_We__.tex
+++ b/subsection_Direct_Fit_Method_We__.tex
...
\begin{equation}
c_v=\frac{1}{L}\frac{d\theta}{dB}
\end{equation}
where L is the length of the solenoid, which is 0.1m in our
case. case.\newline
In this way, we get:
$$V_{c}=20.7\pm 0.845\frac{radians}{T \cdot m}$$
%We fit our data to a function of the form $V=V_{0}sin(\phi)^2$. We could find $\frac{\Delta V}{\delta \phi}$ by taking the derivative and using φ=45 degrees, and we could find ΔV by taking the difference of the voltage read by the photodetector when the laser is on (at maximum voltage read) and off. We could then find Δφ by calculating how much the angle of maximum transmission through the polarizer shifter. With all of this information, we could find dB/dφand use the equation $\frac{\Delta B}{\Delta \phi}=\frac{1}{L}\times\frac{1}{C_{v}}$ to find the Verdet constant of the glass tube.