From 2a22421ece6be81568fd9b01b6b8e0c34607f69b Mon Sep 17 00:00:00 2001 From: "Eugeniy E. Mikhailov" Date: Fri, 8 Oct 2021 15:07:45 -0400 Subject: pre-lab edits --- single-photon-interference_prelab.tex | 23 +++++++++++++++++++---- 1 file changed, 19 insertions(+), 4 deletions(-) diff --git a/single-photon-interference_prelab.tex b/single-photon-interference_prelab.tex index 0244254..6192b41 100644 --- a/single-photon-interference_prelab.tex +++ b/single-photon-interference_prelab.tex @@ -7,13 +7,28 @@ You can use the lab report template to prepare the submission of the pre-lab exe \section*{1. Theoretical graph} -This lab uses the most complex fitting functions of all. Make plots of Eqs.(1) and (2) using reasonable guesses for the necessary parameters (for example, the slit width $a$ is on the order of a $100~\mu$m, the two slits are separated by several slit widths, laser wavelength is $\lambda = 650$~nm, and the distance between the slits and the viewing screen is $\ell \approx 50$~cm). - -What would happen if we increased or decreased $d$, $a$, $\lambda$ and $\ell$. Record your observations, and use these insights in setting the initial parameters when fitting your experimental data. +This lab uses the most complex fitting functions of all. Make a plot (with a computer!) of equation 1 using reasonable guesses for the necessary parameters. For example, the slit width $a$ is on the order of a $100~\mu$m, the two slits are separated by several slit widths, the laser wavelength is $\lambda = 650$~nm, and the distance between the slits and the viewing screen is $\ell \approx 50$~cm). You can assume $I_0=1$. Make sure you create enough points along the x axis to clearly see the features of the plot (refer to figure 6). A range of $-0.5