katyhuff/hw08-template

## hw08-template
% use the answers clause to get answers to print; otherwise leave it out.
\documentclass[11pt,answers,addpoints]{exam}
%\documentclass[11pt]{exam}
\RequirePackage{amssymb, amsfonts, amsmath, latexsym, verbatim, xspace, setspace, mathrsfs}
\usepackage{graphicx}

% By default LaTeX uses large margins.  This doesn't work well on exams; problems
% end up in the "middle" of the page, reducing the amount of space for students
% to work on them.
\usepackage[margin=1in]{geometry}
\usepackage{enumerate}
\usepackage[hidelinks]{hyperref}

% Here's where you edit the Class, Exam, Date, etc.
\newcommand{\class}{NPRE 247}
\newcommand{\term}{Fall 2018}
\newcommand{\assignment}{HW 8}
\newcommand{\duedate}{2018.10.19}
%\newcommand{\timelimit}{50 Minutes}

\newcommand{\nth}{n\ensuremath{^{\text{th}}} }
\newcommand{\ve}[1]{\ensuremath{\mathbf{#1}}}
\newcommand{\Macro}{\ensuremath{\Sigma}}
\newcommand{\vOmega}{\ensuremath{\hat{\Omega}}}

% For an exam, single spacing is most appropriate
\singlespacing
% \onehalfspacing
% \doublespacing

% For an exam, we generally want to turn off paragraph indentation
\parindent 0ex

%\unframedsolutions

\begin{document}

% These commands set up the running header on the top of the exam pages
\pagestyle{head}
\firstpageheader{}{}{\makebox[0.5\textwidth]{Name: \enspace\hrulefill}}
\runningheader{\class}{\assignment\ - Page \thepage\ of \numpages}{Due \duedate}
\runningheadrule

\class \hfill \term \\
\assignment \hfill Due \duedate\\
\rule[1ex]{\textwidth}{.1pt}
%\hrulefill

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\begin{itemize}
        \item Show your work.
        \item This work must be submitted online as a \textbf{single}
                \texttt{.pdf} file through Compass2g.
        \item Work completed with LaTeX or Jupyter earns 1 extra point. Submit
                source file (e.g. \texttt{.tex} or \texttt{.ipynb}) along with
                the \texttt{.pdf} file.
        \item If this work is completed with the aid of a numerical program
                (such as Python, Wolfram Alpha, or MATLAB) all scripts and data
                must be submitted in addition to the \texttt{.pdf}.
        \item If you work with anyone else, document what you worked on together.
\end{itemize}
\rule[1ex]{\textwidth}{.1pt}


% ---------------------------------------------
\begin{questions}

        % ---------------------------------------------
        \question (Shultis \& Faw 6.17) In a particular neutron-induced fission
        of $^{235}U$, 4 prompt neutrons are produced and one fission fragment
        is $^{121}Ag$.
        \begin{parts}
                \part[5] What is the other fission fragment?
                \begin{solution}

                \end{solution}
                \part[5] How much energy is liberated promptly (i.e., before the fission fragments begin to decay)?
                \begin{solution}

                \end{solution}
                \part[5] If the total initial kinetic energy of the fission fragments is 150 MeV, what is the initial kinetic energy of each?
                \begin{solution}

                \end{solution}
		\part[5] What is the total kinetic energy shared by the four prompt neutrons.
                \begin{solution}

                \end{solution}
        \end{parts}

% ---------------------------------------------
        \question (Shultis \& Faw 6.18) Consider the following fission reaction where $^{90}Kr$ and
        $^{142}Ba$ are the initial fission fragments.
        \begin{align}
                ^1_0n + ^{235}U \longrightarrow ^{90}Kr + ^{142}Ba + 4 ( ^1_0n ) + 6 \gamma\\
        \end{align}
        \begin{parts}
                \part[5] What is the fission product chain created by each of these fission fragments?
                \begin{solution}

                \end{solution}
                \part[5] What is the equivalent fission reaction taken to the stable end fission products?
                \begin{solution}

                \end{solution}
                \part[5] How  much energy is liberated promptly?
                \begin{solution}

                \end{solution}

                \part[5] What is the total energy eventually emitted?
                \begin{solution}

                \end{solution}
        \end{parts}

        % ---------------------------------------------
        \question (Shultis \& Faw 6.21) An accident in a fuel reprocessing plant, caused by improper
        mixing of $^{235}U$, produced a burst of fission energy liberating
        energy equivalent to the detonation of 7 kg of TNT (4.2 GJ/ton = 4.6
        kJ/g). About 80\% of the fission products were retained in the
        building.

        \begin{parts}
                \part[5]  How many fissions occurred?
                \begin{solution}

                \end{solution}
                \part[5] Three months after the accident, what is the rate (W) at which energy is released by all the fission products left in the building?
                \begin{solution}

                \end{solution}
        \end{parts}

% ---------------------------------------------
        \question (Shultis \& Faw 7.1)  A broad beam of neutrons is
        normally incident on a homogeneous slab 6-cm thick. The intensity of
        neutrons transmitted through the slab without inter- actions is found
        to be 40\% of the incident intensity.
        \begin{parts}
                \part[5] What is the total interaction coefficient $\mu t$ for the slab
                material?
                \begin{solution}
                        SOLUTION HERE
                \end{solution}
                \part[5] What is the average distance a neutron travels in
                this material before undergoing an interaction?
                \begin{solution}
                        SOLUTION HERE
                \end{solution}
        \end{parts}


        % ---------------------------------------------
        \question[10] Based on the interaction coefficients tabulated in
        Appendix C, plot the tenth- thickness (in centimeters) versus photon
        energy from 0.1 to 10 MeV for water, concrete, iron, and lead.
                \begin{solution}

                \end{solution}

        % ---------------------------------------------
        \question Consider two adjacent infinite homogeneous slabs numbered,
        from left to right, 1 and 2. The slab thickness and total interaction
        coefficients are $t_i$ and $\mu_i$ (i = 1, 2). Normally incident on the
        left slab is a beam of gamma rays.
        \begin{parts}
                \part[5] What is the probability a gamma rays has its first interaction slab 1?
                \begin{solution}
                \end{solution}

                \part[5] What is the probability a gamma ray has its first interaction in slab 2?
                \begin{solution}
                \end{solution}

                \part[5] What is the probability a gamma ray penetrates both slabs without interacting?
                \begin{solution}
                \end{solution}

        \end{parts}

\end{questions}


%\bibliographystyle{plain}
%\bibliography{hw01}
\end{document}
	% use the answers clause to get answers to print; otherwise leave it out.
	\documentclass[11pt,answers,addpoints]{exam}
	%\documentclass[11pt]{exam}
	\RequirePackage{amssymb, amsfonts, amsmath, latexsym, verbatim, xspace, setspace, mathrsfs}
	\usepackage{graphicx}

	% By default LaTeX uses large margins. This doesn't work well on exams; problems
	% end up in the "middle" of the page, reducing the amount of space for students
	% to work on them.
	\usepackage[margin=1in]{geometry}
	\usepackage{enumerate}
	\usepackage[hidelinks]{hyperref}

	% Here's where you edit the Class, Exam, Date, etc.
	\newcommand{\class}{NPRE 247}
	\newcommand{\term}{Fall 2018}
	\newcommand{\assignment}{HW 8}
	\newcommand{\duedate}{2018.10.19}
	%\newcommand{\timelimit}{50 Minutes}

	\newcommand{\nth}{n\ensuremath{^{\text{th}}} }
	\newcommand{\ve}[1]{\ensuremath{\mathbf{#1}}}
	\newcommand{\Macro}{\ensuremath{\Sigma}}
	\newcommand{\vOmega}{\ensuremath{\hat{\Omega}}}

	% For an exam, single spacing is most appropriate
	\singlespacing
	% \onehalfspacing
	% \doublespacing

	% For an exam, we generally want to turn off paragraph indentation
	\parindent 0ex

	%\unframedsolutions

	\begin{document}

	% These commands set up the running header on the top of the exam pages
	\pagestyle{head}
	\firstpageheader{}{}{\makebox[0.5\textwidth]{Name: \enspace\hrulefill}}
	\runningheader{\class}{\assignment\ - Page \thepage\ of \numpages}{Due \duedate}
	\runningheadrule

	\class \hfill \term \\
	\assignment \hfill Due \duedate\\
	\rule[1ex]{\textwidth}{.1pt}
	%\hrulefill

	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
	\begin{itemize}
	\item Show your work.
	\item This work must be submitted online as a \textbf{single}
	\texttt{.pdf} file through Compass2g.
	\item Work completed with LaTeX or Jupyter earns 1 extra point. Submit
	source file (e.g. \texttt{.tex} or \texttt{.ipynb}) along with
	the \texttt{.pdf} file.
	\item If this work is completed with the aid of a numerical program
	(such as Python, Wolfram Alpha, or MATLAB) all scripts and data
	must be submitted in addition to the \texttt{.pdf}.
	\item If you work with anyone else, document what you worked on together.
	\end{itemize}
	\rule[1ex]{\textwidth}{.1pt}



	% ---------------------------------------------
	\begin{questions}

	% ---------------------------------------------
	\question (Shultis \& Faw 6.17) In a particular neutron-induced fission
	of $^{235}U$, 4 prompt neutrons are produced and one fission fragment
	is $^{121}Ag$.
	\begin{parts}
	\part[5] What is the other fission fragment?
	\begin{solution}

	\end{solution}
	\part[5] How much energy is liberated promptly (i.e., before the fission fragments begin to decay)?
	\begin{solution}

	\end{solution}
	\part[5] If the total initial kinetic energy of the fission fragments is 150 MeV, what is the initial kinetic energy of each?
	\begin{solution}

	\end{solution}
	\part[5] What is the total kinetic energy shared by the four prompt neutrons.
	\begin{solution}

	\end{solution}
	\end{parts}

	% ---------------------------------------------
	\question (Shultis \& Faw 6.18) Consider the following fission reaction where $^{90}Kr$ and
	$^{142}Ba$ are the initial fission fragments.
	\begin{align}
	^1_0n + ^{235}U \longrightarrow ^{90}Kr + ^{142}Ba + 4 ( ^1_0n ) + 6 \gamma\\
	\end{align}
	\begin{parts}
	\part[5] What is the fission product chain created by each of these fission fragments?
	\begin{solution}

	\end{solution}
	\part[5] What is the equivalent fission reaction taken to the stable end fission products?
	\begin{solution}

	\end{solution}
	\part[5] How much energy is liberated promptly?
	\begin{solution}

	\end{solution}

	\part[5] What is the total energy eventually emitted?
	\begin{solution}

	\end{solution}
	\end{parts}

	% ---------------------------------------------
	\question (Shultis \& Faw 6.21) An accident in a fuel reprocessing plant, caused by improper
	mixing of $^{235}U$, produced a burst of fission energy liberating
	energy equivalent to the detonation of 7 kg of TNT (4.2 GJ/ton = 4.6
	kJ/g). About 80\% of the fission products were retained in the
	building.

	\begin{parts}
	\part[5] How many fissions occurred?
	\begin{solution}

	\end{solution}
	\part[5] Three months after the accident, what is the rate (W) at which energy is released by all the fission products left in the building?
	\begin{solution}

	\end{solution}
	\end{parts}

	% ---------------------------------------------
	\question (Shultis \& Faw 7.1) A broad beam of neutrons is
	normally incident on a homogeneous slab 6-cm thick. The intensity of
	neutrons transmitted through the slab without inter- actions is found
	to be 40\% of the incident intensity.
	\begin{parts}
	\part[5] What is the total interaction coefficient $\mu t$ for the slab
	material?
	\begin{solution}
	SOLUTION HERE
	\end{solution}
	\part[5] What is the average distance a neutron travels in
	this material before undergoing an interaction?
	\begin{solution}
	SOLUTION HERE
	\end{solution}
	\end{parts}


	% ---------------------------------------------
	\question[10] Based on the interaction coefficients tabulated in
	Appendix C, plot the tenth- thickness (in centimeters) versus photon
	energy from 0.1 to 10 MeV for water, concrete, iron, and lead.
	\begin{solution}

	\end{solution}

	% ---------------------------------------------
	\question Consider two adjacent infinite homogeneous slabs numbered,
	from left to right, 1 and 2. The slab thickness and total interaction
	coefficients are $t_i$ and $\mu_i$ (i = 1, 2). Normally incident on the
	left slab is a beam of gamma rays.
	\begin{parts}
	\part[5] What is the probability a gamma rays has its first interaction slab 1?
	\begin{solution}
	\end{solution}

	\part[5] What is the probability a gamma ray has its first interaction in slab 2?
	\begin{solution}
	\end{solution}

	\part[5] What is the probability a gamma ray penetrates both slabs without interacting?
	\begin{solution}
	\end{solution}

	\end{parts}

	\end{questions}



	%\bibliographystyle{plain}
	%\bibliography{hw01}
	\end{document}