CH Thesis
Introduction
At the Idaho Accelerator Center in Pocatello, Idaho, knowing how much dose is deposited during experiments is important to know due to requests from customers using the accelerator center. This can be achieved by gaining an understanding of how reproducible nanoDot\textsuperscript{tm} Optically Stimulated Luminescence (OSLs) dosimeters. The OSLs can be calibrated by exposing them to a known source, which leads to well understood measurements when in the experimental setting.
Apparatus
\chapter{Experimental Apparatus}
\section{\textsuperscript{137}Cesium Source}
A 9.3 Ci \textsuperscript{137}Cs source was used to calibrate the OSLs and gain an understanding of the relationship between PMT counts and exposure. A system of interlocks is used to safely expose the OSLs. There is an acrylic face plate bolted to the front of the pig, at a set distance of 11.2cm. A sample is positioned 30 cm from the faceplate of the source. Once the interlock requirements have been satisfied, the air supply is turned on allowing the shutter to be opened. \newpage \begin{figure}[H]
\centering
\includegraphics[width =0.6\textwidth]{Content/Apparatus/Cs_Source.jpeg}
\caption{Containment unit for the Cs-137 source.}
\label{fig:result}
\end{figure}
The exposure rate from the source is determined based on the distance (D) from the source, the activity (A) of the source, and a constant ($\Gamma$). The exposure rate for any given distance is calculated in units of Roentgen/hr using the equation \begin{displaymath} \dot R = \frac {\Gamma A }{ D^2} \end{displaymath} A gamma factor of ${\Gamma} = 0.33 \frac {(m^2)(R)}{(Ci)(hr)} $ and activity ${A} = 9.3\ Ci$ is used in these calculations. The distance from the faceplate to the surface of the source needs to be taken into account given the inverse squared distance dependency of the exposure rate. The total distance D is then, D = (Distance to faceplate +0.112m).
With the exposure rate found using these known variables, it is possible to find the total exposure given to the OSLs by integrating the exposure rate over the time the OSL was exposed to the source,
\begin{displaymath}
R_{tot}=\int\limits_{t_0}^{t_f}\dot R\ dt
\end{displaymath}
It is necessary when working with exposure to be able to convert to the units supplied by the OSL reader as the two quantities are directly related. By the unit conversion of 1.4554 Roentgen = 1 Rad, a relationship between PMT counts and calculated exposure can be determined.
\section{25B Linac}
The RF frequency of the IAC's S-Band 25B Linac is 2856 MHz with an energy range of 4 - 25 MeV. With peak currents being easily able to hit 100mA, and pulse widths from 50 ns to 4 $\mu$s, this accelerator is fully capable to operate at the simulated parameters of 8 MeV, 500 ns pulse width, and 50 mA peak current.
\begin{figure}[H]
\centering
\includegraphics[width =0.4\textwidth]{Content/Apparatus/Accelerator.jpg}
\includegraphics[width =0.4\textwidth]{Content/Apparatus/0degree_port.jpg}
\caption{(Left) Accelerator gun. (Right) 0$^{\circ}$ port leading to end of beam pipe.}
\label{fig:result}
\end{figure}
\section{OSL Reader}
The MicroStar i reader manufactured by Landauer is used to measure the radiation dose absorbed by the OSL crystal. By inserting an OSL into the reader, the crystal structure is exposed to an LED, and a photomultiplier tube on the opposing side is used to measure the photons luminescing from the crystal.
% The LED shines onto the crystal and the PMT counts the number of photons emitted from the crystal. \begin{figure}[H]
\centering
\includegraphics[width =0.6\textwidth, angle=270]{Content/Apparatus/OSL_Reader_Front.JPG}
% \includegraphics[width =0.6\textwidth, angle=270]{Content/Apparatus/OSL_Reader_Top.JPG}
\caption{Front of OSL reader.}
\label{fig:result}
\end{figure}
\begin{figure}[H]
\centering
\includegraphics[width =0.6\textwidth]{Content/Apparatus/OSL_Holder.JPG}
\caption{OSL Holder.}
\label{fig:result}
\end{figure} The OSL reader has software capable of calibrating the reader, through which low dose and high dose calibrations are created. These different calibrations give separate calibration factors. To create the calibrations for the software, Landauer supplies pre-dosed OSLs providing five measurements to encompass the device's dynamic range. Due to uncertainty in exposure between dosing and usage, a custom calibration is used to reduce error in succeeding measurements. The OSL reader calculates the dose based on the observed number of PMT counts (N\textsubscript{PMT}), OSL sensitivity (Q\textsubscript{OSL}), and calibration factor (C\textsubscript{f}). The equation used for this calculation is: \begin{displaymath} Dose (mRad) = \frac{N\textsubscript{PMT}}{(C\textsubscript{f})(Q\textsubscript{OSL})} \end{displaymath}
%\section{Beta Source} \newpage \section{Experimental Procedure} \subsection{Photon Beam} To expose the OSLs to a photon beam, a one inch thick aluminum brick and sweeper magnet were inserted at 50 cm from the end of the beam pipe. The aluminum brick was used as the converter followed by the sweeper magnet to redirect any charged particles away from the photon beam. An array of 17 OSLs was placed at a distance of one meter from the end of the beam pipe and then irradiated. This setup was irradiated twice, with different arrays of OSLs to gather dose per pulse information for the photon beam. Each array was exposed to approximately 52000 pulses at a rep rate of 250Hz.
\begin{figure}[H]
\centering
\includegraphics[width =0.75\textwidth]{Content/Data_Analysis/Sweeper_Brick2.JPG}
\includegraphics[width =0.75\textwidth]{Content/Data_Analysis/Sweeper_Brick.JPG}
\caption{(Top)ooking in the direction of beam travel to see front face of the aluminum brick. (Bottom) Sweeping magnet used to change the direction of travel of all charged particles.}
\label{fig:result}
\end{figure}
(See Appendix A for run plan)
\begin{figure}[H]
\centering
\includegraphics[width =0.9\textwidth]{Content/Data_Analysis/Square_Array_Photons.png}
\caption{Average dose of the two arrays irradiated by the photon beam. Each square corresponds to the physical size and location of each OSL irradiated.}
\label{fig:result}
\end{figure}
\subsection{Electron Beam}
Exposing OSLs to an electron beam is accomplished by placing an OSL in front of the 25B Linac at the IAC. By taping an OSL to a glass plate at 50 cm from end of beam pipe, and using a laser centered on the end of the beam pipe, the OSL can be exposed to electrons on-axis for the beam. This setup is used to gather dose per pulse information.
To discern dose per pulse and reproducibility information from the measurements of the electron beam, the OSLs are subjected to the same beam characteristics through the custom run-plan. These characteristics consist of a beam energy of 8 MeV, pulse width of 500 ns, and a peak current of 50 mA. By varying the number of pulses which impinge upon the OSLs, a pulse versus dose relationship can be established.
Once single OSLs had been irradiated on-axis, a 4 x 4 array of 16 OSLs was inserted and exposed to the electron beam. As the 4 x 4 array did not allow for a symmetric orientation while having an OSL centered on-axis, the future arrays were modified to consist of 17 OSLs. This modification created more data points for the on-axis dose per pulse measurements. The OSLs were measured before and after irradiation to see how much dose was deposited.
\begin{figure}[H]
\centering
\includegraphics[width =0.5\textwidth, angle=90]{Content/Data_Analysis/16_OSL_Array.JPG}
\includegraphics[width =0.65\textwidth]{Content/Data_Analysis/17_OSL_Array.JPG}
\caption{(Left) Array of 16 OSLs mounted for irradiation. (Right) Array of 17 OSLs mounted for irradiation.}
\label{fig:result}
\end{figure}
\begin{figure}[H]
\centering
\includegraphics[width =0.9\textwidth]{Content/Data_Analysis/Electron_Array3_Thesis_Image.png}
\caption{Calculated dose from the OSLs irradiated in the electron beam. Each square corresponds to the physical size and location of each OSL irradiated.}
\end{figure}
Data Analysis
\chapter{Data Analysis}
Procedure
\section{Experimental Procedure}
Exposing OSLs to a pure electron beam is accomplished by placing an OSL in front of the 25B Linac at the IAC. By taping an OSL to a glass plate at 50 cm from end of beam pipe, and using a laser centered on the end of the beam pipe, the OSL can be exposed to electrons on-axis for the beam. This setup is used to gather dose per pulse information.
To discern dose per pulse and reproducibility information from the measurements of the electron beam, the OSLs are subjected to the same beam characteristics through the custom run-plan. These characteristics consist of a beam energy of 8 MeV, pulse width of 500 ns, and a peak current of 50 mA. By varying the number of pulses which impinge upon the OSLs, a pulse versus dose relationship can be established.
Once single OSLs had been irradiated on-axis, a 4 x 4 array of 16 OSLs was inserted and exposed to the electron beam. As the 4 x 4 array did not allow for a symmetric orientation while having an OSL centered on-axis, the future arrays were modified to consist of 17 OSLs. This modification created more data points for the on-axis dose per pulse measurements. The OSLs were measured before and after irradiation to see how much dose was deposited.
Following the electron beam irradiation, a one inch thick aluminum brick and sweeper magnet were inserted at 50 cm from the end of the beam pipe to create a photon beam. Two arrays of 17 OSLs were irradiated with approximately 52000 pulses each, at a distance of one meter.
(See Appendix A for run plan)
Experimental Data
\section{Experimental Data} \subsection{Electron Beam} Starting with single OSLs positioned on-axis for the electron beam, each was irradiated with two to six pulses. (See run plan for more details) Using the OSL reader, PMT counts for each OSL are measured. The dose can then be calculated using PMT counts and the high dose calibration. Following the reading of the OSLs, the raw data and calculated uncertainties are input into a text file and fed into a data analysis script. This script takes the text file and interprets it into multiple images. As the OSLs are discrete, a square 3 dimensional array is created with +X (beam right) and +Y (beam up) coordinates, along with the dose intensity on the Z axis. To gather information on the shape of the incident beam, two profiles are created along the diagonals of the arrays.
After irradiation, the OSLs were analyzed using the OSL reader. The measured PMT Counts were used to calculate the average dose per pulse through the high dose calibration. The mean dose per pulse for the electron beam study is 213.87 $\pm$ 3.06 Rad. The dose for each PMT measurement was calculated via the fit for the high dose calibration.
Photon Beam
\subsection{Photon Beam} After irradiating OSLs with a purely electron beam, a water cooled aluminum brick is inserted 50 cm from the end of the beam pipe. This brick is used as a converter and beam stop, which is then followed by a sweeping magnet to redirect any charged particles that may have successfully traversed the beam stop. This setup creates a photon beam that is used to irradiate the OSLs. An array of 17 OSLs is then placed at a distance of one meter from the end of the beam pipe.
The dose the OSL absorbs from the photon field is less per pulse than that of the electron beam. This was determined by irradiating an array with a small number of pulses and reading the central OSL. Once the aluminum brick and sweeper magnet had been inserted, two arrays of 17 OSLs were irradiated at a distance of 1 meter.
The OSLs exposed on axis to the photon beam created with the aluminum brick had an average dose per pulse reading of 10.32075703 $\pm$ 0.3006436468 mRad.
Figure 38 is the X = Y average diagonal of the photon arrays and figure 39 is the same but X = -Y. At a distance of one meter, the incident photon beam is symmetric and flat. Looking at the whole array in figure 37 shows the same result.
Experimental Uncertainty
\subsection{Experimental Uncertainty}
Any measured dose in this experiment has an uncertainty that is propagated through from the high dose calibration. All of the doses were calculated directly from the measured PMT counts and then input into the following:
Following these calculations, the average dose per pulse can be calculated through
Where the $\sigma_{i}$ is the uncertainty in the dose and $dose_{i}$ is the dose calculation with no sigma.
With the standard deviation calculated for each individual measurement, the relative percent error is found with the same formula as in section 3.4, except with PMT counts replaced with dose.
The calculations for the relative errors yield 4.12\% for each measurement. This relative error shows that the dose can be known within $\pm$4.12\%. The result of 4.12\% is also consistent with the relative error average for the calibration measurements shown in figure 37.
Conclusion
\chapter{Conclusion} The calibration is key in understanding the response of the OSLs to a wide range of doses. Without being certain of the exposure the calibration OSLs have been subjected to, there can be some unknown uncertainty in the calibration. By quantifying this uncertainty, any succeeding measurements are better understood.
Calculating the experimental uncertainty and propagating the uncertainty through from the high dose calibration led to the result that the OSLs are reproducible in the range of 460-1440 Rad to $\pm$4.12\%. To follow this result, the mean dose for the on-axis electron beam 213.87 Rad $\pm$1.43\%.
=