custom styled thesis

thesis2/chapters/chap1_intro.tex

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+\chapter*{Introduction}
+\thispagestyle{empty}
+\addcontentsline{toc}{chapter}{Introduction}
+\label{cha:introduction}
+
+%% Restart the numbering to make sure that this is definitely page #1!
+\pagenumbering{arabic}
+
+
+%\begin{itemize}
+  %\item CLFV in 3 lines
+  %\item COMET in 3 lines
+  %\item structure of the thesis:
+    %\begin{itemize}
+      %\item physics motivation of CLFV, COMET (chap 1)
+      %\item overview of COMET, Phase-I, requirements for detectors (chap 2)
+      %\item details of the proton measurements:
+        %\begin{itemize}
+          %\item physics (chap 3)
+          %\item method (chap 4)
+          %\item experimental set up, calibration (chap 4? or 5 )
+          %\item data analysis (chap 5)
+          %\item results, impact (chap 6)
+        %\end{itemize}
+    %\end{itemize}
+%\end{itemize}
+%\begin{comment}
+%The Standard Model (SM) is the most successful theory of particle physics 
+%as it could account for almost all experimental data from high energy
+%experiments. The discovery of a Higgs-like boson at the LHC in 2012 is another
+%triumph of the theory. However, it is known that the SM has its limitations,
+%one example is there is no explanation for the existence of lepton
+%flavours and flavour conservation.
+%theory. For example, it does not explain the origin of mass, the nature of dark
+%matter, or neutrino oscillations.
+
+%The lepton flavour conservation in the SM is assured by assuming neutrinos are
+%massless. But, extensive experiments with atmospheric, solar, accelerator,
+%reactor neutrinos have shown that neutrinos have non-zero masses, and they do
+%mix between flavours~\cite{BeringerArguin.etal.2012}. In other words, lepton
+%flavour violation (LFV) does occur in neutrino oscillations.
+
+%While lepton flavour is totally violated in the neutrino sector, no charged
+%lepton flavour violation (CLFV) has ever been observed. Therefore, any
+%experimental evidence of lepton flavour violation with charged lepton would be
+%a breakthrough that leads to new physics beyond the SM.
+%\end{comment}
+%The Standard Model (SM) is the most successful theory of particle physics 
+%as it could account for almost all experimental data from high energy
+%experiments. However, it is also known that the SM has its 
+%TODO: wording /duplicaitons
+The COMET experiment~\cite{COMET.2007}, proposed at the Japan Proton
+Accelerator Research Complex (J-PARC), is a next-generation-experiment that
+searches for evidence of charged lepton flavour violation (CLFV) with muons.
+The branching ratio of CLFV in the Standard Model, even with massive neutrinos,
+is prohibitively small, at the order of $10^{-54}$. Therefore, any experimental
+observation of CLFV would be a clear signal of new physics beyond the SM.
+
+The COMET (\textbf{CO}herent \textbf{M}uon to \textbf{E}lectron
+\textbf{T}ransition) Collaboration aims to probe the conversion of a muon to
+an electron in a nucleus field at a sensitivity of $6\times10^{-17}$, pushing
+for a four orders of magnitude improvement from the current limit set by the
+SINDRUM-II~\cite{Bertl.etal.2006}. A staging approach is adopted at the COMET
+to achieve an intermediate physics result, as well as to gain operational
+experience. The first stage, COMET Phase I, is scheduled to start in 2016 with
+the goal sensitivity of $3\times 10^{-15}$ after a three-month-running period. 
+
+A cylindrical drift chamber being developed by the Osaka University group
+will be the main tracking detector in the COMET Phase I. It is anticipated that 
+the chamber will be heavily occupied by protons emitted after nuclear muon
+capture in the stopping target, and thus an absorber will be installed to
+reduce the proton hit rate to a tolerable level. A study of proton emission
+following nuclear muon capture for optimisation of the proton absorber is
+presented in this thesis.
+
+The thesis is structured as follows: 
+firstly,
+the physics motivation of the COMET experiment, with muon's normal decays and
+CLFV decays, is described in Chapter~\ref{cha:clfv}.
+Chapter~\ref{cha:comet_overview} gives an overview of the
+COMET experiment: beam lines, detectors and their requirements, and expected
+sensitivities. Details of the study on proton emission are described in
+Chapters~\ref{cha:alcap_phys},~\ref{cha:the_alcap_run_2013},~\ref{cha:data_analysis}:
+physics, method, experimental set up, data analysis. The results and impacts of
+the study on COMET Phase-I design is discussed in
+Chapter~\ref{cha:discussions}.
+
+% chapter introduction (end)