Difference between revisions of "Raw Text"

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Each of the OSLs are labeled with a unique serial number that is used to uniquely identify an OSL with a specific spatial location. Having the position of each OSL logged during experiments yields off axis dose information for the incident beam, as well as a measurement of radiation field intensity as a function of position.
 
Each of the OSLs are labeled with a unique serial number that is used to uniquely identify an OSL with a specific spatial location. Having the position of each OSL logged during experiments yields off axis dose information for the incident beam, as well as a measurement of radiation field intensity as a function of position.
\newpage
+
 
\begin{figure}[H]
 
    \centering
 
    \includegraphics[width =0.4\textwidth]{Content/Apparatus/Closed_Nanodot_Front.JPG}
 
    \includegraphics[width =0.5\textwidth]{Content/Apparatus/Open_Nanodot.JPG}
 
    \caption{(Left) Front of a nanoDot\textsuperscript{tm} OSL with serial number. (Right) Back of a nanoDot\textsuperscript{tm} OSL with exposed crystal.}
 
    \label{fig:result}
 
\end{figure}
 
 
The OSLs are capable of being irradiated multiple times. To reset the OSLs for reuse, each is subjected to a Verilux HappyLight\textsuperscript{\textregistered} Deluxe. The light source outputs a full spectrum of light, leading to an intense white glow. The manufacturer claims there is no UV light output. Each OSL is read prior to use which allows for background subtracted doses and photomultiplier tube (PMT) counts to be used in the calibration and experimental settings. These background subtracted quantities yield the direct change in value due to the exposure subjected to the OSL.  
 
The OSLs are capable of being irradiated multiple times. To reset the OSLs for reuse, each is subjected to a Verilux HappyLight\textsuperscript{\textregistered} Deluxe. The light source outputs a full spectrum of light, leading to an intense white glow. The manufacturer claims there is no UV light output. Each OSL is read prior to use which allows for background subtracted doses and photomultiplier tube (PMT) counts to be used in the calibration and experimental settings. These background subtracted quantities yield the direct change in value due to the exposure subjected to the OSL.  
  
Line 33: Line 26:
  
 
Add link to landauer website for OSL reader as a source for more information.  
 
Add link to landauer website for OSL reader as a source for more information.  
\begin{figure}[H]
 
    \centering
 
    \includegraphics[width =0.8\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, angle=270]{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 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:
 
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}
 
  
 
=Cs 137=
 
=Cs 137=
Line 59: Line 36:
  
 
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.  
 
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.  
\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  
 
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 +0.112cm).  
 
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 +0.112cm).  
  
  
 
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,  
 
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.  
 
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.  
  
Line 90: Line 58:
  
  
\begin{figure}[H]
+
 
    \centering
 
    \includegraphics[width =0.9\textwidth]{Content/Apparatus/LowDose.png}
 
    %    \includegraphics[width =0.6\textwidth]{Content/Apparatus/HighDose.png}
 
    \caption{Low Dose Calibration.}
 
    \label{fig:result}
 
\end{figure}
 
\newpage
 
\begin{figure}[H]
 
    \centering
 
%    \includegraphics[width =0.6\textwidth]{Content/Apparatus/LowDose.png}
 
        \includegraphics[width =0.9\textwidth]{Content/Apparatus/HighDose.png}
 
    \caption{High Dose Calibration.}
 
    \label{fig:result}
 
\end{figure}
 
  
 
Multiple OSLs were exposed to the Cs-137 source for the same amount of time and then each was measured by the OSL reader. The PMT counts were recorded and a standard deviation was determined by:
 
Multiple OSLs were exposed to the Cs-137 source for the same amount of time and then each was measured by the OSL reader. The PMT counts were recorded and a standard deviation was determined by:
\begin{displaymath}
+
 
\sigma = \sqrt{\frac{\Sigma(x_{i}\ -\ \bar x)^{2}}{n\ -\ 1}}
 
\end{displaymath}
 
 
Where $x_{i}$ is each PMT measurement and $\bar x$ is the average of the PMT counts and n is the number of OSLs subjected to the same exposure.  
 
Where $x_{i}$ is each PMT measurement and $\bar x$ is the average of the PMT counts and n is the number of OSLs subjected to the same exposure.  
 
The standard deviation was used as the uncertainty in the PMT counts for the calibration. The Cs-137 source has a 30.17 yr half life, leading to a static activity during the time of irradiation, as such, no uncertainty can be established in calculated exposure.  
 
The standard deviation was used as the uncertainty in the PMT counts for the calibration. The Cs-137 source has a 30.17 yr half life, leading to a static activity during the time of irradiation, as such, no uncertainty can be established in calculated exposure.  
  
 
With the standard deviations in the PMT counts calculated, the relative error for each calculated exposure can be calculated. The relative percent error is found by  
 
With the standard deviations in the PMT counts calculated, the relative error for each calculated exposure can be calculated. The relative percent error is found by  
\begin{displaymath}
+
 
Rel. Err.=\frac{\sigma_{PMT}}{PMT\ Average}*100\%
 
\end{displaymath}
 
\begin{figure}[H]
 
    \centering
 
%    \includegraphics[width =0.6\textwidth]{Content/Apparatus/LowDose.png}
 
        \includegraphics[width =0.9\textwidth]{Content/Apparatus/Relative_Error.png}
 
    \caption{High Dose Calibration.}
 
    \label{fig:result}
 
\end{figure}
 
  
 
=Linac=
 
=Linac=
Line 129: Line 72:
 
\newpage
 
\newpage
 
\section{25B Linac}
 
\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.
+
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}
 

Revision as of 16:08, 28 June 2018

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{Optically Stimulated Luminescence Dosimeters}

OSLs

The nanoDot\textsuperscript{tm} OSL is a carbon-doped aluminum oxide crystal with diameter of 0.501 $\pm$ 0.007 cm and a thickness of cm $\pm$ cm. These dimensions yield an average volume of (propagated error from DIAMETER and thickness). This crystal is contained within a (1 $\pm$ 0.001 cm) x (1 $\pm$ 0.002 cm) x (0.196 $\pm$ 0.002 cm) ABS plastic square to stop the crystal annealing in daylight.

Each of the OSLs are labeled with a unique serial number that is used to uniquely identify an OSL with a specific spatial location. Having the position of each OSL logged during experiments yields off axis dose information for the incident beam, as well as a measurement of radiation field intensity as a function of position.

The OSLs are capable of being irradiated multiple times. To reset the OSLs for reuse, each is subjected to a Verilux HappyLight\textsuperscript{\textregistered} Deluxe. The light source outputs a full spectrum of light, leading to an intense white glow. The manufacturer claims there is no UV light output. Each OSL is read prior to use which allows for background subtracted doses and photomultiplier tube (PMT) counts to be used in the calibration and experimental settings. These background subtracted quantities yield the direct change in value due to the exposure subjected to the OSL.

add link to landauer website for OSLs as a source for more information.

OSL Reader

\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 opacity, see Fig. 22. The OSL reader is a blue box of dimensions 32.75cm x 23.25cm x 10.5cm. On the left side of the front face is the drawer in which an OSL in a holder is inserted. Once the drawer is shut, the black knob on the front is turned from H/P to E1, opening the OSL and exposing the crystal to an LED. The LED shines onto the crystal and the PMT counts the number of photons emitted from the crystal.

Add link to landauer website for OSL reader as a source for more information.


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:

Cs 137

\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.


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

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 +0.112cm).


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,

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.

Calibration

\section{nanoDot\textsuperscript{tm} OSL Calibration}

The response of the nanoDot\textsuperscript{tm} OSLs to electrons and photons can be quantified in terms of dose using a calibration. Initial attempts to calibrate the OSLs were to follow the manufacturers guidelines, through which two different calibrations are created; a high dose, and a low dose. The low dose calibration is used by the OSL reader when the measured dose is less than 10000 mRad, and the high dose is used for any values exceeding 10000 mRad. These calibrations are created by reading in pre-dosed OSLs provided by Landauer so the OSL reader software can create a linear fit between PMT counts and dose. Using these calibrations assumes that the pre-dosed OSLs have not been subjected to any other exposure during the shipping and storing before use. It was this assumption that led to the creation of a custom calibration using a Cs-137 source. Using a source of known activity allows for calculated exposure rates and a well understood calibration as there is less uncertainty in the dose on the OSL.

By subjecting the OSLs to a known total exposure, it is possible to eliminate the effect of any unknown factors that could have invalidated the listed dose on the pre-dosed OSLs supplied by Landauer. Therefore to establish the relationship between background subtracted PMT counts and total exposure for the OSLs, a custom calibration was needed. This calibration is used in lieu of the calibration given by the OSL reader.

To begin the calibration, a set of fifteen previously unexposed OSLs is chosen at random and exposed to the 9.3Ci Cesium-137 source.



Multiple OSLs were exposed to the Cs-137 source for the same amount of time and then each was measured by the OSL reader. The PMT counts were recorded and a standard deviation was determined by:

Where $x_{i}$ is each PMT measurement and $\bar x$ is the average of the PMT counts and n is the number of OSLs subjected to the same exposure. The standard deviation was used as the uncertainty in the PMT counts for the calibration. The Cs-137 source has a 30.17 yr half life, leading to a static activity during the time of irradiation, as such, no uncertainty can be established in calculated exposure.

With the standard deviations in the PMT counts calculated, the relative error for each calculated exposure can be calculated. The relative percent error is found by


Linac

\newpage \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.