==== Day 2 Analysis ====
Complete the following set of analysis exercises and **submit by 11:59 pm the day //before// you are due back in lab**.
- For the 662 keV peak of Cs-137 (with no absorber present), show the full method of count rate estimation using the in-software tools. Include the following:
* an annotated figure (screenshot or replotted data) showing the identification of the region of interest you chose,
* estimation of the number of counts in the background and the net counts in the peak (above background) within that region of interest, and
* determination of the net count rate and uncertainty in the net count rate (with details of the calculations).
- For the same 662 keV peak of Cs-137 (with no absorber present), show the full method of count rate estimation using a least-squares fit to a Gaussian plus background. Include the following:
* show the mathematical model used in the fit;
* the plot showing showing the data used in the fit with the full fit function overlayed on top;
* all fit parameters (with uncertainties) and the reduced chi-square value for the fit.
- Show a plot of the count rate (either rate $R$ or normalized rate $R/R_0$) of 662 keV gammas as a function of aluminum absorber thickness, with an exponential fit to the data. Include the following:
* show the mathematical model used as the fit function;
* the plot showing showing the data (and uncertainties) used in the fit with the full fit function overlayed on top;
* all fit parameters (with uncertainties) and the reduced chi-square value for the fit;
* a quantitative discussion of the reduced chi-square value;
* the final value for the linear coefficient at this energy, $\lambda(E=662~\textrm{keV})$, with uncertainty; and
* a quantitative discussion of the agreement between your experimental value and the literature value (available [[phylabs:lab_courses:phys-211-wiki-home:introductory-lab-gamma-cross-sections:start#literature_values|below]]).