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@@ -250,7 +250,7 @@ flavour was experimentally verified in the Nobel Prize-winning experiment of
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Danby et al. at Brookhaven National Laboratory
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Danby et al. at Brookhaven National Laboratory
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(BNL)~\cite{DanbyGaillard.etal.1962}. Then the concepts of generations of
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(BNL)~\cite{DanbyGaillard.etal.1962}. Then the concepts of generations of
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particles was developed~\cite{MakiNakagawa.etal.1962}, and integrated into the
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particles was developed~\cite{MakiNakagawa.etal.1962}, and integrated into the
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SM, in which the lepton flavour conservation is guaranteed by and exact
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SM, in which the lepton flavour conservation is guaranteed by an exact
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symmetry, owing to massless neutrinos.
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symmetry, owing to massless neutrinos.
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Following the above LFV searches with muons, searches with various particles,
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Following the above LFV searches with muons, searches with various particles,
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@@ -267,11 +267,11 @@ must be modified to accommodate the massive neutrinos.
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With the massive neutrinos charged lepton flavour violation (CLFV) must occur
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With the massive neutrinos charged lepton flavour violation (CLFV) must occur
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through oscillations in loops. But, CLFV processes are highly suppressed in the
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through oscillations in loops. But, CLFV processes are highly suppressed in the
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SM.
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SM.
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For example, Marciano and Mori ~\cite{MarcianoMori.etal.2008} calculated the
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%\hl{TODO: Feynman diagram}
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For example, Marciano and Mori~\cite{MarcianoMori.etal.2008} calculated the
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branching ratio of the process \mueg to be \brmeg$<10^{-54}$. Other
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branching ratio of the process \mueg to be \brmeg$<10^{-54}$. Other
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CLFV processes with muons are also suppressed to similar practically
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CLFV processes with muons are also suppressed to similar practically
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unmeasurable levels.%\hl{TODO: Feynman diagram}
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unmeasurable levels. Therefore, any experimental
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Therefore, any experimental
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observation of CLFV would be an unambiguous signal of the physics beyond the
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observation of CLFV would be an unambiguous signal of the physics beyond the
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SM. Many theoretical models for physics beyond the SM, including supersymmetric
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SM. Many theoretical models for physics beyond the SM, including supersymmetric
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(SUSY) models, extra dimensional models, little Higgs models, predict
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(SUSY) models, extra dimensional models, little Higgs models, predict
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@@ -308,7 +308,7 @@ significantly larger CLFV
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%It is calculated that there are two CLFV processes that would
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%It is calculated that there are two CLFV processes that would
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%occur at large rates by many new physics models,
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%occur at large rates by many new physics models,
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Among the CLFV processes, the \mueg and
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Among the CLFV processes, the \mueg and
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the \muec are expected to have large effect by many models. The current
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the \muec are expected to have large effect in many models. The current
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experimental limits on these two decay modes are set respectively by the MEG
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experimental limits on these two decay modes are set respectively by the MEG
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experiment~\cite{Adam.etal.2013} and the SINDRUM-II
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experiment~\cite{Adam.etal.2013} and the SINDRUM-II
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experiment~\cite{Bertl.etal.2006}:
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experiment~\cite{Bertl.etal.2006}:
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@@ -63,20 +63,20 @@ and Cooper~\cite{BernsteinCooper.2013}.
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1961 & \sn{4.0}{-6} & Cu & \cite{SardCrowe.etal.1961}\\
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1961 & \sn{4.0}{-6} & Cu & \cite{SardCrowe.etal.1961}\\
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1961 & \sn{5.9}{-6} & Cu & \cite{ConversiLella.etal.1961}\\
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1961 & \sn{5.9}{-6} & Cu & \cite{ConversiLella.etal.1961}\\
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1962 & \sn{2.2}{-7} & Cu & \cite{ConfortoConversi.etal.1962}\\
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1962 & \sn{2.2}{-7} & Cu & \cite{ConfortoConversi.etal.1962}\\
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1964 & \sn{2.2}{-7} & Cu & \cite{ConversiLella.etal.1961}\\
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1964 & \sn{2.2}{-7} & Cu & \cite{BartleyDavies.etal.1964}\\
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1972 & \sn{2.6}{-8} & Cu & \cite{ConversiLella.etal.1961}\\
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1972 & \sn{2.6}{-8} & Cu & \cite{BrymanBlecher.etal.1972}\\
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1977 & \sn{4.0}{-10} & S & \cite{ConversiLella.etal.1961}\\
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1977 & \sn{4.0}{-10} & S & \cite{BadertscherBorer.etal.1977}\\
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1982 & \sn{7.0}{-11} & S & \cite{ConversiLella.etal.1961}\\
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1982 & \sn{7.0}{-11} & S & \cite{BadertscherBorer.etal.1982a}\\
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1988 & \sn{4.6}{-12} & Ti & \cite{ConversiLella.etal.1961}\\
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1988 & \sn{4.6}{-12} & Ti & \cite{AhmadAzuelos.etal.1988a}\\
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1993 & \sn{4.3}{-12} & Ti & \cite{ConversiLella.etal.1961}\\
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1993 & \sn{4.3}{-12} & Ti & \cite{DohmenGroth.etal.1993}\\
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1995 & \sn{6.5}{-13} & Ti & \cite{ConversiLella.etal.1961}\\
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1996 & \sn{4.6}{-11} & Pb & \cite{HoneckerDohmen.etal.1996}\\
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1996 & \sn{4.6}{-11} & Pb & \cite{ConversiLella.etal.1961}\\
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2006 & \sn{7.0}{-13} & Au & \cite{Bertl.etal.2006}\\
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2006 & \sn{7.0}{-13} & Au & \cite{ConversiLella.etal.1961}\\
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\bottomrule
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\bottomrule
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%%TODO fix ref
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\end{tabular}
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\end{tabular}
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\end{center}
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\end{center}
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\caption{History of \mueconv experiments, reproduced
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\caption{History of \mueconv experiments with more and more stringent upper
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from~\cite{BernsteinCooper.2013}}
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limit.}
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\label{tab:mueconv_history}
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\label{tab:mueconv_history}
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\end{table}
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\end{table}
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@@ -94,7 +94,8 @@ muons used in the experiment were \SI{52}{\MeV\per\cc} and
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\SI{53}{\MeV\per\cc}, and the momentum spread was 2\%.
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\SI{53}{\MeV\per\cc}, and the momentum spread was 2\%.
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\begin{figure}[htbp] \centering
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\begin{figure}[htbp] \centering
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\includegraphics[width=0.85\textwidth]{figs/sindrumII_setup}
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\includegraphics[width=0.85\textwidth]{figs/sindrumII_setup}
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\caption{SINDRUM-II set up}
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\caption{SINDRUM-II experimental set up, reprinted from
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reference~\cite{Bertl.etal.2006} with permission from Springer.}
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\label{fig:sindrumII_setup}
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\label{fig:sindrumII_setup}
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\end{figure}
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\end{figure}
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@@ -115,7 +116,9 @@ important in probing better sensitivity.
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\begin{figure}[htbp]
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\begin{figure}[htbp]
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\centering
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\centering
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\includegraphics[width=0.55\textwidth]{figs/sindrumII_Au_result}
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\includegraphics[width=0.55\textwidth]{figs/sindrumII_Au_result}
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\caption{SINDRUM-II results}
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\caption{SINDRUM-II results showing background events reaching into the
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signal region. Reprinted from reference~\cite{Bertl.etal.2006} with
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permission from Springer.}
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%TODO: explain top and bottom figure
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%TODO: explain top and bottom figure
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\label{fig:sindrumII_result}
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\label{fig:sindrumII_result}
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\end{figure}
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\end{figure}
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@@ -353,8 +356,10 @@ Therefore, light material is preferable as muon stopping target.
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The conversion rates are normalised to the rate in aluminium. Four models
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The conversion rates are normalised to the rate in aluminium. Four models
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were considered and noted with letters: D for dipole-interaction-dominated
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were considered and noted with letters: D for dipole-interaction-dominated
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model, V for vector and S for scalar interactions. The three vertical lines
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model, V for vector and S for scalar interactions. The three vertical lines
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from left to right correspond to $Z=13$(Al), $Z=22$(Ti), and $Z=82$(Pb)l
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from left to right correspond to $Z=13$(Al), $Z=22$(Ti), and $Z=82$(Pb)
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respectively.}
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respectively. Reprinted figure from
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reference~\cite{CiriglianoKitano.etal.2009}. Copyright 2009 by the
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American Physical Society.}
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\label{fig:comet_mueconv_RateVsZ}
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\label{fig:comet_mueconv_RateVsZ}
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\end{figure}
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\end{figure}
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@@ -410,10 +410,10 @@ data. There are two reasons for that:
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\end{enumerate}
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\end{enumerate}
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The first study was done by Morigana and Fry~\cite{MorinagaFry.1953} where
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The first study was done by Morigana and Fry~\cite{MorinagaFry.1953} where
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24,000 muon tracks were stopped in their nuclear emulsion which contains silver,
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24,000 muon tracks were stopped in their nuclear emulsion which contains silver,
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bromine, and other light elements, mainly nitrogen, carbon, hydrogen and
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bromine AgBr, and other light elements, mainly nitrogen, carbon, hydrogen and
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oxygen. The authors identified a capture on a light element as it would leave
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oxygen. The authors identified a capture on a light element as it would leave
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a recoil
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a recoil
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track of the nucleus. They found that for silver bromide AgBr, $(2.2 \pm
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track of the nucleus. They found that for silver bromide, $(2.2 \pm
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0.2)\%$ of the captures produced protons and $(0.5 \pm 0.1)\%$ produced alphas.
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0.2)\%$ of the captures produced protons and $(0.5 \pm 0.1)\%$ produced alphas.
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For light elements, the emission rate for proton and alpha are respectively
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For light elements, the emission rate for proton and alpha are respectively
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$(9.5 \pm 1.1)\%$ and $(3.4 \pm 0.7)\%$. Subsequently, Kotelchuk and
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$(9.5 \pm 1.1)\%$ and $(3.4 \pm 0.7)\%$. Subsequently, Kotelchuk and
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@@ -423,9 +423,13 @@ statistics and in fair agreement with Morigana and Fry
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\begin{figure}[htb]
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\begin{figure}[htb]
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\centering
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\centering
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\includegraphics[width=0.65\textwidth]{figs/kotelchuk_proton_spectrum}
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\includegraphics[width=0.65\textwidth]{figs/kotelchuk_proton_spectrum}
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\caption{Early proton spectrum after muon capture in silver bromide AgBr
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\caption{Proton spectrum after muon capture in silver bromide AgBr in
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recorded using nuclear emulsion. Image is taken from
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early experiments recorded using nuclear emulsion. The closed circles
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Ref.~\cite{KotelchuckTyler.1968}}
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are data points from Morigana and Fry~\cite{MorinagaFry.1953}, the
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histogram is measurement result of Kotelchuk and
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Tyler~\cite{KotelchuckTyler.1968}. Reprinted figure from
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reference~\cite{KotelchuckTyler.1968}. Copyright 1968 by the American
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Physical Society.}
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\label{fig:kotelchuk_proton_spectrum}
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\label{fig:kotelchuk_proton_spectrum}
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\end{figure}
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\end{figure}
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@@ -475,16 +479,18 @@ might be at work in this mass range.
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target (closed circle) in the energy range above 40 MeV and an exponential
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target (closed circle) in the energy range above 40 MeV and an exponential
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fit. The open squares are silicon data from Budyashov et
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fit. The open squares are silicon data from Budyashov et
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al.~\cite{BudyashovZinov.etal.1971}, the open triangles are magnesium data
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al.~\cite{BudyashovZinov.etal.1971}, the open triangles are magnesium data
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from Balandin et al.~\cite{BalandinGrebenyuk.etal.1978}.}
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from Balandin et al.~\cite{BalandinGrebenyuk.etal.1978}. Reprinted
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figure from reference~\cite{KraneSharma.etal.1979}. Copyright 1979 by
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the American Physical Society.}
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\label{fig:krane_proton_spec}
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\label{fig:krane_proton_spec}
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\end{figure}
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\end{figure}
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The aforementioned difficulties in charged particle measurements could be
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The aforementioned difficulties in charged particle measurements could be
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solved using an active target, just like nuclear emulsion. Sobottka and
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solved using an active target, just like nuclear emulsion. Sobottka and
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Wills~\cite{SobottkaWills.1968} took this approach when using a Si(Li) detector
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Wills~\cite{SobottkaWills.1968} took this approach when using a Si(Li) detector
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to stop muons. They obtained a spectrum of charged particles up to 26
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to stop muons. They obtained a spectrum of charged particles up to \SI{26}{\MeV}
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\si{\MeV}~in \cref{fig:sobottka_spec}. The peak below 1.4
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in \cref{fig:sobottka_spec}. The peak below \SI{1.4}{\MeV}
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\si{\MeV}~is due to the recoiling $^{27}$Al. The higher energy events
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is due to the recoiling $^{27}$Al. The higher energy events
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including protons, deuterons and alphas constitute $(15\pm 2)\%$ of capture
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including protons, deuterons and alphas constitute $(15\pm 2)\%$ of capture
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events, which is consistent with a rate of $(12.9\pm1.4)\%$ from gelatine
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events, which is consistent with a rate of $(12.9\pm1.4)\%$ from gelatine
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observed by Morigana and Fry. This part has an exponential
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observed by Morigana and Fry. This part has an exponential
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@@ -507,7 +513,8 @@ silicon, and $(17\pm4)\%$ in copper.
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\centering
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\centering
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\includegraphics[width=0.75\textwidth]{figs/sobottka_spec}
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\includegraphics[width=0.75\textwidth]{figs/sobottka_spec}
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\caption{Charged particle spectrum from muon capture in a silicon detector,
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\caption{Charged particle spectrum from muon capture in a silicon detector,
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image taken from Sobottka and Wills~\cite{SobottkaWills.1968}.}
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measured by Sobottka and Wills~\cite{SobottkaWills.1968}. The plot is
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reproduced from the original figure in reference~\cite{SobottkaWills.1968}.}
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\label{fig:sobottka_spec}
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\label{fig:sobottka_spec}
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\end{figure}
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\end{figure}
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@@ -544,7 +551,7 @@ against the Coulomb barrier for the outgoing protons are given in
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%and \cref{fig:wyttenbach_rate_23p}.
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%and \cref{fig:wyttenbach_rate_23p}.
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The classical Coulomb barrier $V$ they used are given by:
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The classical Coulomb barrier $V$ they used are given by:
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\begin{equation}
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\begin{equation}
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V = \frac{zZe^2}{r_0A^{\frac{1}{3}} + \rho},
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V = \frac{zZe^2}{r_0A^{\frac{1}{3}} + \rho}\,,
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\label{eqn:classical_coulomb_barrier}
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\label{eqn:classical_coulomb_barrier}
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\end{equation}
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\end{equation}
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where $z$ and $Z$ are the charges of the outgoing particle and of the residual
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where $z$ and $Z$ are the charges of the outgoing particle and of the residual
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@@ -552,11 +559,15 @@ nucleus respectively, $e^2 = 1.44 \si{\MeV}\cdot\textrm{fm}$, $r_0 = 1.35
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\textrm{ fm}$, and $\rho = 0 \textrm{ fm}$ for protons were taken.
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\textrm{ fm}$, and $\rho = 0 \textrm{ fm}$ for protons were taken.
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\begin{figure}[htb]
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\begin{figure}[htb]
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\centering
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\centering
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\includegraphics[width=0.48\textwidth]{figs/wyttenbach_rate_1p}
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\includegraphics[width=0.48\textwidth]{figs/wyttenbach_rate_1p}
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\includegraphics[width=0.505\textwidth]{figs/wyttenbach_rate_23p}
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\includegraphics[width=0.505\textwidth]{figs/wyttenbach_rate_23p}
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\caption{Activation results from Wyttenbach et
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\caption{Activation results from Wyttenbach and
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al.~\cite{WyttenbachBaertschi.etal.1978} for the $(\mu^-,\nu p)$,
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colleagues~\cite{WyttenbachBaertschi.etal.1978} for the $(\mu^-,\nu p)$,
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$(\mu^-,\nu pn)$, $(\mu^-,\nu p2n)$ and $(\mu^-,\nu p3n)$ reactions.}
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$(\mu^-,\nu pn)$, $(\mu^-,\nu p2n)$ and $(\mu^-,\nu p3n)$ reactions. The
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cross section of each individual channels decreases exponentially as the
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Coulomb barrier for proton emission increases.
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Reprinted figure from reference~\cite{WyttenbachBaertschi.etal.1978} with
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permission from Elsevier.}
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\label{fig:wyttenbach_rate_1p}
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\label{fig:wyttenbach_rate_1p}
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\end{figure}
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\end{figure}
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%\begin{figure}[htb]
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%\begin{figure}[htb]
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@@ -568,10 +579,10 @@ nucleus respectively, $e^2 = 1.44 \si{\MeV}\cdot\textrm{fm}$, $r_0 = 1.35
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%\label{fig:wyttenbach_rate_23p}
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%\label{fig:wyttenbach_rate_23p}
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%\end{figure}
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%\end{figure}
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Wyttenbach et al.\ saw that the cross section of each reaction decreases
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Wyttenbach and colleagues saw that the cross section of each reaction decreases
|
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exponentially with increasing Coulomb barrier. The decay constant for all
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exponentially with increasing Coulomb barrier. The decay constant for all
|
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$(\mu^-,\nu pxn)$ is about 1.5 per \si{\MeV}~of Coulomb barrier. They
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$(\mu^-,\nu pxn)$ is about 1.5 per \si{\MeV}~of Coulomb barrier. They
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also commented a ratio for different de-excitation channels:
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also observed a ratio for different de-excitation channels:
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\begin{equation}
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\begin{equation}
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(\mu^-,\nu p):(\mu^-,\nu pn):(\mu^-,\nu p2n):(\mu^-,\nu p3n) = 1:6:4:4,
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(\mu^-,\nu p):(\mu^-,\nu pn):(\mu^-,\nu p2n):(\mu^-,\nu p3n) = 1:6:4:4,
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\label{eqn:wyttenbach_ratio}
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\label{eqn:wyttenbach_ratio}
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@@ -581,7 +592,7 @@ the results from Vil'gel'mova et al.~\cite{VilgelmovaEvseev.etal.1971} as being
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too high, but Measday~\cite{Measday.2001} noted it it is not
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too high, but Measday~\cite{Measday.2001} noted it it is not
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necessarily true since there has been suggestion from other experiments that
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necessarily true since there has been suggestion from other experiments that
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$(\mu^-, \nu p)$ reactions might become more important for light nuclei.
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$(\mu^-, \nu p)$ reactions might become more important for light nuclei.
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Measday also commented that the ratio~\eqref{eqn:wyttenbach_ratio} holds over
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Measday noted that the ratio~\eqref{eqn:wyttenbach_ratio} holds over
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a broad range of mass, but below $A=40$ the $(\mu^-,\nu p)$ reaction can vary
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a broad range of mass, but below $A=40$ the $(\mu^-,\nu p)$ reaction can vary
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significantly from nucleus to nucleus.
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significantly from nucleus to nucleus.
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% subsection experimental_status (end)
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% subsection experimental_status (end)
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@@ -598,24 +609,25 @@ $\rho(p) \sim A/(B^2 + p^2)^2$; (II) Fermi gas at zero temperature; and (III)
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Fermi gas at a finite temperature ($kT = 9$ \si{\MeV}).
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Fermi gas at a finite temperature ($kT = 9$ \si{\MeV}).
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|
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A very good agreement with the experimental result for the alpha emission was
|
A very good agreement with the experimental result for the alpha emission was
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obtained with distribution (III), both in the absolute percentage and the energy
|
obtained with distribution (III).
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distribution (curve (III) in the left hand side of
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%, both in the absolute percentage and the energy
|
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\cref{fig:ishii_cal_result}). However, the calculated emission of protons
|
%distribution (curve (III) in the left hand side of
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at the same temperature falls short by about 10
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%\cref{fig:ishii_cal_result}).
|
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times compares to the data. The author also found that the distribution
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However, the calculated emission rate of protons at the same temperature was 10
|
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(I) is unlikely to be suitable for proton emission, and using that distribution
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times smaller the experimental results from Morigana and Fry. The author
|
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for alpha emission resulted in a rate 15 times larger than observed.
|
found the distribution (I) is unlikely to be suitable for proton emission,
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and using that distribution
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for alpha emission resulted in a rate 15 times larger than the observed rate.
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|
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\begin{figure}[htb]
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%\begin{figure}[htb]
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\centering
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%\centering
|
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\includegraphics[width=.49\textwidth]{figs/ishii_cal_alpha}
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%\includegraphics[width=.49\textwidth]{figs/ishii_cal_alpha}
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%\hspace{10mm}
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%\includegraphics[width=.49\textwidth]{figs/ishii_cal_proton}
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\includegraphics[width=.49\textwidth]{figs/ishii_cal_proton}
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%\caption{Alpha spectrum (left) and proton spectrum (right) from Ishii's
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\caption{Alpha spectrum (left) and proton spectrum (right) from Ishii's
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%calculation~\cite{Ishii.1959} in comparison with experimental data from
|
||||||
calculation~\cite{Ishii.1959} in comparison with experimental data from
|
%Morigana and Fry. Image is taken from Ishii's paper.}
|
||||||
Morigana and Fry. Image is taken from Ishii's paper.}
|
%\label{fig:ishii_cal_result}
|
||||||
\label{fig:ishii_cal_result}
|
%\end{figure}
|
||||||
\end{figure}
|
|
||||||
Singer~\cite{Singer.1974} noted that by assuming a reduced effective mass for
|
Singer~\cite{Singer.1974} noted that by assuming a reduced effective mass for
|
||||||
the nucleon, the average excitation energy increases, but the proton
|
the nucleon, the average excitation energy increases, but the proton
|
||||||
emission rate is not significantly improved and still could not explain the
|
emission rate is not significantly improved and still could not explain the
|
||||||
@@ -650,7 +662,9 @@ spectrum and experimental data is shown in
|
|||||||
\caption{Proton energy spectrum from muon capture in AgBr, the data in
|
\caption{Proton energy spectrum from muon capture in AgBr, the data in
|
||||||
histogram is from Morigana and Fry, calculation by Lifshitz and
|
histogram is from Morigana and Fry, calculation by Lifshitz and
|
||||||
Singer~\cite{LifshitzSinger.1978} showed contributions from the
|
Singer~\cite{LifshitzSinger.1978} showed contributions from the
|
||||||
pre-equilibrium emission and the equilibrium emission.}
|
pre-equilibrium emission and the equilibrium emission. Reprinted figure
|
||||||
|
from reference~\cite{LifshitzSinger.1978}. Copyright 1978 by the American
|
||||||
|
Physical Society.}
|
||||||
\label{fig:lifshitzsinger_cal_proton}
|
\label{fig:lifshitzsinger_cal_proton}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
@@ -689,20 +703,20 @@ al.~\cite{VilgelmovaEvseev.etal.1971} observed.
|
|||||||
$^{31}_{15}$P & 6.7 & {(6.3)} & 35 & {$> 61$}&(91) \\
|
$^{31}_{15}$P & 6.7 & {(6.3)} & 35 & {$> 61$}&(91) \\
|
||||||
$^{39}_{19}$K & 19 & 32 \pm 6 & 67 & {} \\
|
$^{39}_{19}$K & 19 & 32 \pm 6 & 67 & {} \\
|
||||||
$^{41}_{19}$K & 5.1 & {(4.7)} & 30 & {$> 28$} &(70)\\
|
$^{41}_{19}$K & 5.1 & {(4.7)} & 30 & {$> 28$} &(70)\\
|
||||||
%$^{51 }_{23}$V &3.7 &2.9 \pm 0.4 &25 &{$>20 \pm 1.8$}& (32)\\
|
$^{51 }_{23}$V &3.7 &2.9 \pm 0.4 &25 &{$>20 \pm 1.8$}& (32)\\
|
||||||
%$^{55 }_{25}$Mn &2.4 &2.8 \pm 0.4 &16 &{$>26 \pm 2.5$}& (35)\\
|
$^{55 }_{25}$Mn &2.4 &2.8 \pm 0.4 &16 &{$>26 \pm 2.5$}& (35)\\
|
||||||
%$^{59 }_{27}$Co &3.3 &1.9 \pm 0.2 &21 &{$>37 \pm 3.4$}& (50)\\
|
$^{59 }_{27}$Co &3.3 &1.9 \pm 0.2 &21 &{$>37 \pm 3.4$}& (50)\\
|
||||||
%$^{60 }_{28}$Ni &8.9 &21.4 \pm 2.3 &49 &40 \pm 5&\\
|
$^{60 }_{28}$Ni &8.9 &21.4 \pm 2.3 &49 &40 \pm 5&\\
|
||||||
%$^{63 }_{29}$Cu &4.0 &2.9 \pm 0.6 &25 &{$>17 \pm 3 $}& (36)\\
|
$^{63 }_{29}$Cu &4.0 &2.9 \pm 0.6 &25 &{$>17 \pm 3 $}& (36)\\
|
||||||
%$^{65 }_{29}$Cu &1.2 &{(2.3)} &11 &{$>35 \pm 4.5$}& (36)\\
|
$^{65 }_{29}$Cu &1.2 &{(2.3)} &11 &{$>35 \pm 4.5$}& (36)\\
|
||||||
%$^{75 }_{33}$As &1.5 &1.4 \pm 0.2 &14 &{$>14 \pm 1.3$}& (19)\\
|
$^{75 }_{33}$As &1.5 &1.4 \pm 0.2 &14 &{$>14 \pm 1.3$}& (19)\\
|
||||||
%$^{79 }_{35}$Br &2.7 &{} &22 & &\\
|
$^{79 }_{35}$Br &2.7 &{} &22 & &\\
|
||||||
%$^{107}_{47}$Ag &2.3 &{} &18 & &\\
|
$^{107}_{47}$Ag &2.3 &{} &18 & &\\
|
||||||
%$^{115}_{49}$In &0.63 &{(0.77)} &7.2 &{$>11 \pm 1$} &(12)\\
|
$^{115}_{49}$In &0.63 &{(0.77)} &7.2 &{$>11 \pm 1$} &(12)\\
|
||||||
%$^{133}_{55}$Cs &0.75 &0.48 \pm 0.07 &8.7 &{$>4.9 \pm 0.5$} &(6.7)\\
|
$^{133}_{55}$Cs &0.75 &0.48 \pm 0.07 &8.7 &{$>4.9 \pm 0.5$} &(6.7)\\
|
||||||
%$^{165}_{67}$Ho &0.26 &0.30 \pm 0.04 &4.1 &{$>3.4 \pm 0.3$} &(4.6)\\
|
$^{165}_{67}$Ho &0.26 &0.30 \pm 0.04 &4.1 &{$>3.4 \pm 0.3$} &(4.6)\\
|
||||||
%$^{181}_{73}$Ta &0.15 &0.26 \pm 0.04 &2.8 &{$>0.7 \pm 0.1$} &(3.0)\\
|
$^{181}_{73}$Ta &0.15 &0.26 \pm 0.04 &2.8 &{$>0.7 \pm 0.1$} &(3.0)\\
|
||||||
%$^{208}_{82}$Pb &0.14 &0.13 \pm 0.02 &1.1 &{$>3.0 \pm 0.8$} &(4.1)\\
|
$^{208}_{82}$Pb &0.14 &0.13 \pm 0.02 &1.1 &{$>3.0 \pm 0.8$} &(4.1)\\
|
||||||
\bottomrule
|
\bottomrule
|
||||||
\end{tabular}
|
\end{tabular}
|
||||||
\end{center}
|
\end{center}
|
||||||
@@ -710,11 +724,11 @@ al.~\cite{VilgelmovaEvseev.etal.1971} observed.
|
|||||||
reaction $^A_Z X (\mu,\nu p) ^{A-1}_{Z-2}Y$ and for inclusive proton
|
reaction $^A_Z X (\mu,\nu p) ^{A-1}_{Z-2}Y$ and for inclusive proton
|
||||||
emission compiled by Measday~\cite{Measday.2001}. The calculated values
|
emission compiled by Measday~\cite{Measday.2001}. The calculated values
|
||||||
are from Lifshitz and Singer. The experimental data are mostly from
|
are from Lifshitz and Singer. The experimental data are mostly from
|
||||||
Wyttenbach et al.~\cite{WyttenbachBaertschi.etal.1978}. For inclusive emission
|
Wyttenbach and colleagues~\cite{WyttenbachBaertschi.etal.1978}. The
|
||||||
the experimental figures are lower limits, determined from the
|
inclusive emission the experimental figures are lower limits because only
|
||||||
actually measured channels. The figures in crescent parentheses are
|
a few decay channels could be studied. The figures in crescent parentheses
|
||||||
estimates for the total inclusive rate derived from the measured exclusive
|
are estimates for the total inclusive rate derived from the measured
|
||||||
channels by the use of ratio in \eqref{eqn:wyttenbach_ratio}.}
|
exclusive channels by the use of ratio in \eqref{eqn:wyttenbach_ratio}.}
|
||||||
\label{tab:lifshitzsinger_cal_proton_rate}
|
\label{tab:lifshitzsinger_cal_proton_rate}
|
||||||
\end{table}
|
\end{table}
|
||||||
|
|
||||||
@@ -898,50 +912,63 @@ detectors will be assessed by detailed Monte Carlo study using Geant4.
|
|||||||
\subsection{Goals and plan of the experiment}
|
\subsection{Goals and plan of the experiment}
|
||||||
\label{sub:goals_of_the_experiment}
|
\label{sub:goals_of_the_experiment}
|
||||||
|
|
||||||
Our experimental program is organised in three distinct work packages (WP),
|
The goal of the experiment is measure protons following nuclear muon capture
|
||||||
|
on aluminium:
|
||||||
|
\begin{enumerate}
|
||||||
|
\item emission rate,
|
||||||
|
\item and spectrum shape in the lower energy region down to \SI{2.5}{\MeV},
|
||||||
|
\item with a precision of about 5\%.
|
||||||
|
\end{enumerate}
|
||||||
|
The measured proton spectrum and rate will be used to assess the hit rate on
|
||||||
|
the tracking drift chamber of the COMET Phase-I.
|
||||||
|
|
||||||
|
The measurement of protons itself is part of the AlCap, where
|
||||||
|
experimental program is organised in three distinct work packages (WP),
|
||||||
directed by different team leaders, given in parentheses.
|
directed by different team leaders, given in parentheses.
|
||||||
|
|
||||||
\begin{itemize}
|
\begin{itemize}
|
||||||
\item[WP1:] (Kammel (Seattle), Kuno(Osaka)) \textbf{Charged
|
\item[WP1:] (P. Kammel (University of Washington), Y. Kuno(Osaka University))
|
||||||
Particle Emission after Muon Capture.}\\ Protons emitted after nuclear muon
|
\textbf{Charged Particle Emission after Muon Capture.}\\ Protons emitted
|
||||||
capture in the stopping target dominate the single-hit rates in the tracking
|
after nuclear muon
|
||||||
chambers for both the Mu2e and COMET Phase-I experiments. We plan to measure
|
capture in the stopping target dominate the single-hit rates in the tracking
|
||||||
both the total rate and the energy spectrum to a precision of 5\% down to
|
chambers for both the Mu2e and COMET Phase-I experiments. We plan to measure
|
||||||
proton energies of \SI{2.5}{\MeV}.
|
both the total rate and the energy spectrum to a precision of 5\% down to
|
||||||
\item[WP2:] (Lynn(PNNL), Miller(BU))
|
proton energies of \SI{2.5}{\MeV}.
|
||||||
\textbf{Gamma and X-ray Emission after Muon Capture.}\\ A Ge detector will
|
\item[WP2:] (J. Miller(Boston University))
|
||||||
be used to measure X-rays from the muonic atomic cascade, in order to provide
|
\textbf{Gamma and X-ray Emission after Muon Capture.}\\ A germanium detector
|
||||||
the muon-capture normalization for WP1, and is essential for very thin
|
will be used to measure X-rays from the muonic atomic cascade, in order to
|
||||||
stopping targets. It is also the primary method proposed for calibrating the
|
provide
|
||||||
number of muon stops in the Mu2e and COMET experiments. Two additional
|
the muon-capture normalisation for WP1, and is essential for very thin
|
||||||
calibration techniques will also be explored; (1) detection of delayed gamma
|
stopping targets. It is also the primary method proposed for calibrating the
|
||||||
rays from nuclei activated during nuclear muon capture, and (2) measurement
|
number of muon stops in the Mu2e and COMET experiments. Two additional
|
||||||
of the rate of photons produced in radiative muon decay. The first of these
|
calibration techniques will also be explored; (1) detection of delayed gamma
|
||||||
would use a Ge detector and the second a NaI detector. The NaI
|
rays from nuclei activated during nuclear muon capture, and (2) measurement
|
||||||
calorimeter will measure the rate of high energy photons from radiative muon
|
of the rate of photons produced in radiative muon decay. The first of these
|
||||||
capture (RMC), electrons from muon decays in orbit (DIO), and photons from
|
would use a germanium detector and the second a sodium iodine detector.
|
||||||
radiative muon decay (RMD), as potential background sources for the
|
The sodium iodine
|
||||||
conversion measurement. As these rates are expected to be extremely low near
|
calorimeter will measure the rate of high energy photons from radiative muon
|
||||||
the conversion electron energy, only data at energies well below 100 MeV will
|
capture (RMC), electrons from muon decays in orbit (DIO), and photons from
|
||||||
be obtained.
|
radiative muon decay (RMD), as potential background sources for the
|
||||||
\item[WP3:] (Hungerford(UH), Winter(ANL)) \textbf{Neutron
|
conversion measurement. As these rates are expected to be extremely low near
|
||||||
Emission after Muon Capture.}\\ Neutron rates and spectra after capture in
|
the conversion electron energy, only data at energies well below 100 MeV will
|
||||||
Al and Ti are not well known. In particular, the low energy region below 10
|
be obtained.
|
||||||
MeV is important for determining backgrounds in the Mu2e/COMET detectors and
|
\item[WP3:] (E. Hungerford (University of Houston), P. Winter(Argonne
|
||||||
veto counters as well as evaluating the radiation damage to electronic
|
National Laboratory)) \textbf{Neutron
|
||||||
components. Carefully calibrated liquid scintillation detectors, employing
|
Emission after Muon Capture.}\\ Neutron rates and spectra after capture in
|
||||||
neutron-gamma discrimination and spectrum unfolding techniques, will measure
|
Al and Ti are not well known. In particular, the low energy region below 10
|
||||||
these spectra. The measurement will attempt to obtain spectra as low or lower
|
MeV is important for determining backgrounds in the Mu2e/COMET detectors and
|
||||||
than 1 MeV up to 10 MeV. \\
|
veto counters as well as evaluating the radiation damage to electronic
|
||||||
|
components. Carefully calibrated liquid scintillation detectors, employing
|
||||||
|
neutron-gamma discrimination and spectrum unfolding techniques, will measure
|
||||||
|
these spectra. The measurement will attempt to obtain spectra as low or lower
|
||||||
|
than 1 MeV up to 10 MeV. \\
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
|
|
||||||
WP1 is the most developed
|
WP1 was the most developed project in this program with most of the associated
|
||||||
project in this program with most of the associated apparatus has been built and
|
apparatus had been built and optimised. Therefore the measurement of proton has
|
||||||
optimized. We are ready to start this experiment in 2013, while preparing and
|
been carried out in November and December 2013, while preparing and completing
|
||||||
completing test measurements and simulations to undertake WP2 and WP3.
|
test measurements and simulations to undertake WP2 and WP3.
|
||||||
|
|
||||||
The measurement of proton has been carried out in November and December 2013,
|
|
||||||
the details are described in following chapters.
|
|
||||||
% subsection goals_of_the_experiment (end)
|
% subsection goals_of_the_experiment (end)
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||||
% section the_alcap_experiment (end)
|
% section the_alcap_experiment (end)
|
||||||
|
|||||||
@@ -18,7 +18,7 @@ provide veto signals for the silicon and germanium detectors. Two liquid
|
|||||||
scintillators for neutron measurements were also tested in this run.
|
scintillators for neutron measurements were also tested in this run.
|
||||||
\begin{figure}[btp]
|
\begin{figure}[btp]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.65\textwidth]{figs/alcap_setup_detailed}
|
\includegraphics[width=0.95\textwidth]{figs/alcap_setup_detailed}
|
||||||
\caption{AlCap detectors: two silicon packages inside the vacuum vessel,
|
\caption{AlCap detectors: two silicon packages inside the vacuum vessel,
|
||||||
muon beam detectors including plastic scintillators and a wire chamber,
|
muon beam detectors including plastic scintillators and a wire chamber,
|
||||||
germanium detector and veto plastic scintillators.}
|
germanium detector and veto plastic scintillators.}
|
||||||
@@ -30,9 +30,11 @@ Muons in the $\pi$E1 beam line are decay products of pions created
|
|||||||
as a \SI{590}{\mega\electronvolt} proton beam hits a thick carbon target. The
|
as a \SI{590}{\mega\electronvolt} proton beam hits a thick carbon target. The
|
||||||
beam line was designed to deliver muons with momenta ranging from
|
beam line was designed to deliver muons with momenta ranging from
|
||||||
\SIrange{10}{500}{\mega\electronvolt\per\cc} and momentum spread from
|
\SIrange{10}{500}{\mega\electronvolt\per\cc} and momentum spread from
|
||||||
\SIrange{0.26}{8.0}{\percent}~\cite{Foroughli.1997}. These parameters can be
|
\SIrange{0.26}{8.0}{\percent}~\cite{Foroughli.1997}. The beam parameters can
|
||||||
selected by changing various magnets and slits shown in
|
be tuned by adjusting magnets and slits along the beam line.
|
||||||
\cref{fig:psi_piE1_elements}.
|
%These parameters can be
|
||||||
|
%selected by changing various magnets and slits
|
||||||
|
%\cref{fig:psi_piE1_elements}.
|
||||||
|
|
||||||
%(E-target in \cref{fig:psi_exp_hall_all}).
|
%(E-target in \cref{fig:psi_exp_hall_all}).
|
||||||
%\begin{figure}[p]
|
%\begin{figure}[p]
|
||||||
@@ -44,40 +46,46 @@ selected by changing various magnets and slits shown in
|
|||||||
%\label{fig:psi_exp_hall_all}
|
%\label{fig:psi_exp_hall_all}
|
||||||
%\end{figure}
|
%\end{figure}
|
||||||
|
|
||||||
\begin{figure}[btp]
|
%\begin{figure}[btp]
|
||||||
\centering
|
%\centering
|
||||||
\includegraphics[width=0.7\textwidth]{figs/psi_piE1_elements}
|
%\includegraphics[width=0.7\textwidth]{figs/psi_piE1_elements}
|
||||||
\caption{The $\pi$E1 beam line}
|
%\caption{The $\pi$E1 beam line}
|
||||||
\label{fig:psi_piE1_elements}
|
%\label{fig:psi_piE1_elements}
|
||||||
\end{figure}
|
%\end{figure}
|
||||||
|
|
||||||
One of the main requirements of the AlCap experiment was a low energy muon beam
|
One of the main requirements of the AlCap experiment was a low energy muon beam
|
||||||
with narrow momentum bite in order to achieve a high fraction of stopping muons
|
with narrow momentum bite in order to achieve a high fraction of stopping muons
|
||||||
in the very thin targets. In this Run 2013, muons from
|
in the very thin targets. In this Run 2013, muons from
|
||||||
\SIrange{28}{45}{\mega\electronvolt\per\cc} and momentum spread of 1\% and
|
\SIrange{28}{45}{\MeV\per\cc} and momentum spread of 1\% and
|
||||||
3\%, respectively, were used.
|
3\% were used.
|
||||||
|
|
||||||
For part of the experiment the target was replaced with one of the silicon
|
For part of the experiment the target was replaced with one of the silicon
|
||||||
detector packages allowed an accurate momentum and range calibration
|
detector packages allowed an accurate momentum and range calibration
|
||||||
%(via range-energy relations)
|
%(via range-energy relations)
|
||||||
of the beam at the target. \Cref{fig:Rates} shows the measured muon rates
|
of the beam at the target. \Cref{fig:Rates} shows the measured muon rates
|
||||||
as a function of momentum for two different momentum bites.
|
as a function of momentum for two different momentum bites.
|
||||||
\Cref{fig:Beam} shows an example of the resulting energy spectra.
|
\Cref{fig:Beam} shows an example of the resulting energy spectra recorded by
|
||||||
|
our silicon detector.
|
||||||
\begin{figure}[btp]
|
\begin{figure}[btp]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.6\textwidth]{figs/Rates.png}
|
\includegraphics[width=0.65\textwidth]{figs/Rates.png}
|
||||||
\caption{Measured muon rate (kHz) at low momenta. Momentum bite of 3 and 1 \%
|
\caption{Measured muon rates at low momenta during the Run 2013. Beam rates
|
||||||
FWHM, respectively.}
|
at 1 \% FWHM momentum bite were about 3 times smaller than the rates at
|
||||||
|
3 \% FWHM.}
|
||||||
\label{fig:Rates}
|
\label{fig:Rates}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
\begin{figure}[btp]
|
\begin{figure}[btp]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.9\textwidth]{figs/beam.pdf}
|
\includegraphics[width=1.00\textwidth]{figs/beam.pdf}
|
||||||
\caption{Energy deposition at \SI{36.4}{/c} incident muon beam in an
|
\caption{Energy deposition at \SI{36.4}{/c} incident muon beam in an
|
||||||
\SI{1500}{\micro\meter}-thick active target. The peak at low energy is due
|
\SI{1500}{\micro\meter}-thick active target. The peak at low energy is due
|
||||||
to beam electrons, the peaks at higher energies are due to muons. Momentum
|
to beam electrons, the peaks at higher energies are due to muons. Momentum
|
||||||
bite of 1 and 3\% FWHM on left and right hand side, respectively.}
|
bite of 1 and 3\% FWHM on left and right hand side, respectively. The
|
||||||
|
electron peak are the same in both plots as beam electrons are minimum
|
||||||
|
ionisation particles and passed though the detector easily. The muon peak
|
||||||
|
at the 3 \% FWHM momentum bite is notably broader than that at 1 \% FWHM
|
||||||
|
setting.}
|
||||||
\label{fig:Beam}
|
\label{fig:Beam}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
@@ -254,19 +262,25 @@ The germanium detector is
|
|||||||
a GMX20P4-70-RB-B-PL, n-type, coaxial high purity germanium detector produced
|
a GMX20P4-70-RB-B-PL, n-type, coaxial high purity germanium detector produced
|
||||||
by ORTEC. The detector was optimised for low energy gamma and X-rays
|
by ORTEC. The detector was optimised for low energy gamma and X-rays
|
||||||
measurement with an ultra-thin entrance window of 0.5-mm-thick beryllium and
|
measurement with an ultra-thin entrance window of 0.5-mm-thick beryllium and
|
||||||
a 0.3-\si{\micro\meter}-thick ion implanted contact (\cref{fig:ge_det_dimensions}).
|
a 0.3-\si{\micro\meter}-thick ion implanted contact. The germanium crystal is
|
||||||
This detector is equipped with a transistor reset preamplifier which,
|
\SI{52.5}{\mm} in diameter, and \SI{55.3}{\mm} in length. The axial well has
|
||||||
according to the producer, enables it to work in an ultra-high rate environment
|
a diameter of \SI{9.9}{\mm} and \SI{47.8}{\mm} deep.
|
||||||
|
%(\cref{fig:ge_det_dimensions}).
|
||||||
|
|
||||||
|
ORTEC quoted the energy resolution of the detector is \SI{1.90}{\keV} at the
|
||||||
|
\SI{1.73}{\MeV} gamma line. The detector is equipped with a transistor reset
|
||||||
|
preamplifier which, according to the producer, enables it to work in an
|
||||||
|
ultra-high rate environment
|
||||||
up to $10^6$ counts\si{\per\second} at \SI{1}{\mega\electronvolt}.
|
up to $10^6$ counts\si{\per\second} at \SI{1}{\mega\electronvolt}.
|
||||||
\begin{figure}[btp]
|
%\begin{figure}[btp]
|
||||||
\centering
|
%\centering
|
||||||
\includegraphics[width=0.9\textwidth]{figs/ge_det_dimensions}
|
%\includegraphics[width=0.9\textwidth]{figs/ge_det_dimensions}
|
||||||
\caption{Dimensions of the germanium detector}
|
%\caption{Dimensions of the germanium detector}
|
||||||
\label{fig:ge_det_dimensions}
|
%\label{fig:ge_det_dimensions}
|
||||||
\end{figure}
|
%\end{figure}
|
||||||
|
|
||||||
The detector was installed outside of the vacuum chamber at 32 cm from the
|
The detector was installed outside of the vacuum chamber at 32 cm from the
|
||||||
target, seeing the target through a 10-mm-thick aluminium window, behind
|
target, viewing the target through a 10-mm-thick aluminium window, behind
|
||||||
a plastic scintillator counter used to veto electrons. Liquid nitrogen
|
a plastic scintillator counter used to veto electrons. Liquid nitrogen
|
||||||
necessary for the operation of the detector had to be refilled every 8 hours.
|
necessary for the operation of the detector had to be refilled every 8 hours.
|
||||||
A timer was set up in the data acquisition system to remind this.
|
A timer was set up in the data acquisition system to remind this.
|
||||||
@@ -837,12 +851,12 @@ algorithm that takes the pulse parameters from the peak of the waveform. In
|
|||||||
parallel, a pulse finding and template fitting code is being developed because
|
parallel, a pulse finding and template fitting code is being developed because
|
||||||
it would provide more accurate pulse information. The first iteration of this
|
it would provide more accurate pulse information. The first iteration of this
|
||||||
code has been completed and is being tested.
|
code has been completed and is being tested.
|
||||||
\begin{figure}[btp]
|
%\begin{figure}[btp]
|
||||||
\centering
|
%\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/analysis_scheme}
|
%\includegraphics[width=0.85\textwidth]{figs/analysis_scheme}
|
||||||
\caption{Concept of the analysis framework in \rootana{}}
|
%\caption{Concept of the analysis framework in \rootana{}}
|
||||||
\label{fig:rootana_scheme}
|
%\label{fig:rootana_scheme}
|
||||||
\end{figure}
|
%\end{figure}
|
||||||
|
|
||||||
After obtaining pulse parameters for individual channel, the pairing up of
|
After obtaining pulse parameters for individual channel, the pairing up of
|
||||||
fast and slow pulses from the same physical detector needs to be done. This
|
fast and slow pulses from the same physical detector needs to be done. This
|
||||||
@@ -1030,10 +1044,15 @@ shown in \cref{fig:lldq}.
|
|||||||
\includegraphics[width=0.47\textwidth]{figs/lldq_noise}
|
\includegraphics[width=0.47\textwidth]{figs/lldq_noise}
|
||||||
\includegraphics[width=0.47\textwidth]{figs/lldq_tdiff}
|
\includegraphics[width=0.47\textwidth]{figs/lldq_tdiff}
|
||||||
\caption{Example trend plots used in the low level data quality checking:
|
\caption{Example trend plots used in the low level data quality checking:
|
||||||
noise level in FWHM (left) and time correlation with muon hits (right). The
|
noise level in FWHM (left) and time correlation with muon hits (right).
|
||||||
|
The horizontal axis is run number, the vertical axis is the channel name
|
||||||
|
(left), or the time difference between hit in the germanium
|
||||||
|
detector and a hit in upstream counter (right). Colors in both plots
|
||||||
|
indicate the number of events. In the left plot, the
|
||||||
noise level was basically stable in in this data set, except for one
|
noise level was basically stable in in this data set, except for one
|
||||||
channel. On the right hand side, this sanity check helped find out the
|
channel where there was a sudden jump in a range of runs. On the right hand
|
||||||
sampling frequency was wrongly applied in the first tranche of the data
|
side, this sanity check helped find out the sampling frequency was wrongly
|
||||||
|
applied in the first tranche of the data
|
||||||
set.}
|
set.}
|
||||||
\label{fig:lldq}
|
\label{fig:lldq}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|||||||
@@ -1,13 +1,18 @@
|
|||||||
\chapter{Data analysis and results}
|
\chapter{Data analysis and results}
|
||||||
\label{cha:data_analysis}
|
\label{cha:data_analysis}
|
||||||
This chapter presents initial analysis on subsets of the collected data.
|
This chapter presents the first analysis on subsets of the collected data for
|
||||||
|
the aluminium 100-\si{\um}-thick target. The analysis use information from
|
||||||
|
silicon, germanium, and upstream muon detectors. Pulse parameters were
|
||||||
|
extracted from waveforms by the simplest method of peak sensing (as mentioned
|
||||||
|
in \cref{sub:offline_analyser}).
|
||||||
Purposes of the analysis include:
|
Purposes of the analysis include:
|
||||||
\begin{itemize}
|
\begin{itemize}
|
||||||
\item testing the analysis chain;
|
\item testing the analysis chain;
|
||||||
\item verification of the experimental method, specifically the
|
\item verification of the experimental method, specifically the
|
||||||
normalisation of number of stopped muons, and particle identification
|
normalisation of number of stopped muons, and particle identification
|
||||||
using specific energy loss;
|
using specific energy loss;
|
||||||
\item extracting a preliminary rate of proton emission from aluminium.
|
\item extracting a preliminary rate and spectrum of proton emission from
|
||||||
|
aluminium.
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
|
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||||
@@ -22,10 +27,8 @@ methods:
|
|||||||
\item inferred from number of X-rays recorded by the germanium detector.
|
\item inferred from number of X-rays recorded by the germanium detector.
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
This analysis was done on a subset of the active target runs
|
This analysis was done on a subset of the active target runs
|
||||||
\numrange{2119}{2140} because of the problem of wrong clock frequency found in
|
\numrange{2119}{2140}, which contains \num{6.43E7} muon events.
|
||||||
the data quality checking shown in \cref{fig:lldq}. The data set contains
|
|
||||||
%\num[fixed-exponent=2, scientific-notation = fixed]{6.4293720E7} muon events.
|
%\num[fixed-exponent=2, scientific-notation = fixed]{6.4293720E7} muon events.
|
||||||
\num{6.43E7} muon events.
|
|
||||||
|
|
||||||
\subsection{Number of stopped muons from active target counting}
|
\subsection{Number of stopped muons from active target counting}
|
||||||
\label{sub:event_selection}
|
\label{sub:event_selection}
|
||||||
@@ -33,40 +36,49 @@ Because of the active target, a stopped muon would cause two coincident hits on
|
|||||||
the muon counter and the target. The energy of the muon hit on the active
|
the muon counter and the target. The energy of the muon hit on the active
|
||||||
target is also well-defined as the narrow-momentum-spread beam was used. The
|
target is also well-defined as the narrow-momentum-spread beam was used. The
|
||||||
correlation between the energy and timing of all the hits on the active target
|
correlation between the energy and timing of all the hits on the active target
|
||||||
is shown in \cref{fig:sir2f_Et_corr}. The most intense spot at zero time
|
is shown in \cref{fig:sir2f_Et_corr}.
|
||||||
|
|
||||||
|
\begin{figure}[tbp]
|
||||||
|
\centering
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/sir2_sir2f_E_t_corr}
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/sir2_sir2f_amp_1us_slices}
|
||||||
|
\caption{Energy - timing correlation of hits on the active target (top),
|
||||||
|
and the projections onto the energy axis in 1000-\si{\ns}-long slices
|
||||||
|
from \SI{1500}{\ns} (bottom). The prompt peak at roughly \SI{5}{\MeV} in
|
||||||
|
the top plot is muon peak. In the delayed energy spectra, the Michel
|
||||||
|
electrons dominate at early time, then the beam electrons are more
|
||||||
|
clearly seen in longer delay.}
|
||||||
|
\label{fig:sir2f_Et_corr}
|
||||||
|
\end{figure}
|
||||||
|
|
||||||
|
The prompt hits on the active silicon detector are mainly beam particles:
|
||||||
|
muons and electrons. The most intense spot at time zero
|
||||||
and about \SI{5}{\MeV} energy corresponds to stopped muons in the thick target.
|
and about \SI{5}{\MeV} energy corresponds to stopped muons in the thick target.
|
||||||
The band below \SI{1}{\MeV} is due to electrons, either in the beam or from
|
The band below \SI{1}{\MeV} is due to electrons, either in the beam or from
|
||||||
muon decay in orbits, or emitted during the cascading of muon to the muonic 1S
|
muon decay in orbits, or emitted during the cascading of muon to the muonic 1S
|
||||||
state. The valley between time zero and 1200~ns shows the minimum distance in
|
state. The valley between time zero and 1200~ns shows the minimum distance in
|
||||||
time between two pulses. It is the mentioned limitation of the current pulse
|
time between two pulses. It is the limitation of the current pulse
|
||||||
parameter extraction method where no pile up or double pulses is accounted for.
|
parameter extraction method where no pile up or double pulses is accounted for.
|
||||||
|
|
||||||
\begin{figure}[htb]
|
The delayed hits on the active target after 1200~ns are mainly secondary
|
||||||
\centering
|
|
||||||
\includegraphics[width=0.85\textwidth]{figs/sir2_sir2f_E_t_corr}
|
|
||||||
\caption{Energy - timing correlation of hits on the active target.}
|
|
||||||
\label{fig:sir2f_Et_corr}
|
|
||||||
\end{figure}
|
|
||||||
|
|
||||||
The hits on the silicon active target after 1200~ns are mainly secondary
|
|
||||||
particles from the stopped muons:
|
particles from the stopped muons:
|
||||||
\begin{itemize}
|
\begin{itemize}
|
||||||
\item electrons from muon decay in the 1S orbit
|
\item electrons from muon decay in the 1S orbit,
|
||||||
\item products emitted after nuclear muon capture, including: gamma, neutron,
|
\item products emitted after nuclear muon capture, including: gamma, neutron,
|
||||||
heavy charged particles and recoiled nucleus
|
heavy charged particles and recoiled nucleus.
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
It can be seen that there is a faint stripe of muons in the time larger than
|
It can be seen that there is a faint stripe of muons in the time larger than
|
||||||
1200~ns region, they are scattered muons by other materials without hitting the
|
1200~ns region, they are scattered muons by other materials without hitting the
|
||||||
muon counter. The electrons in the beam caused the constant band below 1 MeV and
|
muon counter. The electrons in the beam caused the constant band below 1 MeV and
|
||||||
$t > 5000$ ns (see \cref{fig:sir2_1us_slices}).
|
$t > 5000$ ns (see \cref{fig:sir2f_Et_corr} bottom).
|
||||||
\begin{figure}[htb]
|
%\begin{figure}[htb]
|
||||||
\centering
|
%\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/sir2_sir2f_amp_1us_slices}
|
%\includegraphics[width=0.85\textwidth]{figs/sir2_sir2f_amp_1us_slices}
|
||||||
\caption{Energy deposit on the active target in 1000 ns time slices from the
|
%\caption{Energy deposit on the active target in 1000 ns time slices from the
|
||||||
muon hit. The peaks at about 800 keV in large delayed time are from
|
%muon hit. The peaks at about 800 keV in large delayed time are from
|
||||||
the beam electrons.}
|
%the beam electrons.}
|
||||||
\label{fig:sir2_1us_slices}
|
%\label{fig:sir2_1us_slices}
|
||||||
\end{figure}
|
%\end{figure}
|
||||||
|
|
||||||
From the energy-timing correlation above, the cuts to select stopped muons are:
|
From the energy-timing correlation above, the cuts to select stopped muons are:
|
||||||
\begin{enumerate}
|
\begin{enumerate}
|
||||||
@@ -74,19 +86,20 @@ From the energy-timing correlation above, the cuts to select stopped muons are:
|
|||||||
and the first hit on the silicon active target is in coincidence with that
|
and the first hit on the silicon active target is in coincidence with that
|
||||||
muon counter hit:
|
muon counter hit:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\lvert t_{\textrm{target}} - t_{\mu\textrm{ counter}}\rvert \le \SI{50}{\ns}
|
\lvert t_{\textrm{target}} - t_{\mu\textrm{ counter}}\rvert \le
|
||||||
|
\SI{50}{\ns}\,,
|
||||||
\label{eqn:sir2_prompt_cut}
|
\label{eqn:sir2_prompt_cut}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
\item the first hit on the target has energy of that of the muons:
|
\item and the first hit on the target has energy of that of the muons:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
\SI{3.4}{\MeV} \le E_{\textrm{target}} \le \SI{5.6}{\MeV}
|
\SI{3.4}{\MeV} \le E_{\textrm{target}} \le \SI{5.6}{\MeV}\,.
|
||||||
\label{eqn:sir2_muE_cut}
|
\label{eqn:sir2_muE_cut}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
The two cuts~\eqref{eqn:sir2_prompt_cut} and~\eqref{eqn:sir2_muE_cut} give
|
The two cuts~\eqref{eqn:sir2_prompt_cut} and~\eqref{eqn:sir2_muE_cut} give
|
||||||
a number of stopped muons counted by the active target:
|
a number of stopped muons counted by the active target:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
N_{\mu \textrm{ active Si}} = 9.32 \times 10^6
|
N_{\mu \textrm{ active Si}} = 9.32 \times 10^6 \pm 3.0\times10^3\,.
|
||||||
\label{eqn:n_stopped_si_count}
|
\label{eqn:n_stopped_si_count}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
@@ -123,11 +136,19 @@ additional timing cut is applied for the germanium detector hits:
|
|||||||
\lvert t_{\textrm{Ge}} - t_{\mu\textrm{ counter}} \rvert < \SI{500}{\ns}
|
\lvert t_{\textrm{Ge}} - t_{\mu\textrm{ counter}} \rvert < \SI{500}{\ns}
|
||||||
\label{eqn:sir2_ge_cut}
|
\label{eqn:sir2_ge_cut}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
\begin{figure}[!htb]
|
||||||
|
\centering
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/sir2_xray_22}
|
||||||
|
\caption{Prompt muonic X-rays spectrum from the active silicon target. The
|
||||||
|
$(2p-1s)$ X-ray shows up at \SI{400}{\keV}; higher transitions can also
|
||||||
|
be identified.}
|
||||||
|
\label{fig:sir2_xray}
|
||||||
|
\end{figure}
|
||||||
|
|
||||||
The germanium spectrum after three
|
The germanium spectrum after three
|
||||||
cuts~\eqref{eqn:sir2_prompt_cut},~\eqref{eqn:sir2_muE_cut}
|
cuts~\eqref{eqn:sir2_prompt_cut},~\eqref{eqn:sir2_muE_cut}
|
||||||
and~\eqref{eqn:sir2_ge_cut} is plotted in \cref{fig:sir2_xray}. The $(2p-1s)$
|
and~\eqref{eqn:sir2_ge_cut} is plotted in \cref{fig:sir2_xray}. The $(2p-1s)$
|
||||||
line clearly showed up at \SI{400}{\keV} with very low background. A peak at
|
line clearly showed up at \SI{400}{\keV} on a very low background. A peak at
|
||||||
\SI{476}{\keV} is identified as the $(3p-1s)$ transition. Higher transitions
|
\SI{476}{\keV} is identified as the $(3p-1s)$ transition. Higher transitions
|
||||||
such as $(4p-1s)$, $(5p-1s)$ and $(6p-1s)$ can also be recognised at
|
such as $(4p-1s)$, $(5p-1s)$ and $(6p-1s)$ can also be recognised at
|
||||||
\SI{504}{\keV}, \SI{516}{\keV} and \SI{523}{\keV}, respectively.
|
\SI{504}{\keV}, \SI{516}{\keV} and \SI{523}{\keV}, respectively.
|
||||||
@@ -137,25 +158,24 @@ such as $(4p-1s)$, $(5p-1s)$ and $(6p-1s)$ can also be recognised at
|
|||||||
%and the calculated efficiency is $(4.549 \pm 0.108)\times 10^{-5}$ -- a 0.15\%
|
%and the calculated efficiency is $(4.549 \pm 0.108)\times 10^{-5}$ -- a 0.15\%
|
||||||
%increasing from that of the 400.177~keV line, so no attempt for recalibration
|
%increasing from that of the 400.177~keV line, so no attempt for recalibration
|
||||||
%or correction was made.
|
%or correction was made.
|
||||||
\begin{figure}[htb]
|
|
||||||
\centering
|
|
||||||
\includegraphics[width=0.85\textwidth]{figs/sir2_xray_22}
|
|
||||||
\caption{Prompt muonic X-rays spectrum from the active silicon target.
|
|
||||||
}
|
|
||||||
\label{fig:sir2_xray}
|
|
||||||
\end{figure}
|
|
||||||
|
|
||||||
The net area of the $(2p-1s)$ is found to be 2929.7 by fitting a Gaussian
|
The net area of the $(2p-1s)$ is found to be 2929.7 by fitting a Gaussian
|
||||||
peak on top of a first-order polynomial from \SIrange{395}{405}{\keV}.
|
peak on top of a linear background from \SIrange{395}{405}{\keV}.
|
||||||
Using the same procedure of correcting described in
|
Using the same procedure of correcting described in
|
||||||
\cref{sub:germanium_detector}, and taking detector acceptance and X-ray
|
\cref{sub:germanium_detector}, and taking detector acceptance and X-ray
|
||||||
intensity into account (see \cref{tab:sir2_xray_corr}), the number of muon
|
intensity into account (see \cref{tab:sir2_xray_corr}), the number of muon
|
||||||
stopped is:
|
stopped is:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
N_{\mu \textrm{ stopped X-ray}} = (9.16 \pm 0.28)\times 10^6,
|
N_{\mu \textrm{ stopped X-ray}} = (9.16 \pm 0.28)\times 10^6\,,
|
||||||
\label{eqn:n_stopped_xray_count}
|
\label{eqn:n_stopped_xray_count}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
which is consistent with the number of X-rays counted using the active target.
|
which is consistent with the number of X-rays counted using the active target.
|
||||||
|
|
||||||
|
The uncertainty of the number of muons inferred from the X-ray
|
||||||
|
has equal contributions from statistical uncertainty in peak
|
||||||
|
area and systematic uncertainty from efficiency calibration. The relative
|
||||||
|
uncertainty in number of muons is 3\%, good enough for the normalisation in
|
||||||
|
this measurement.
|
||||||
\begin{table}[btp]
|
\begin{table}[btp]
|
||||||
\begin{center}
|
\begin{center}
|
||||||
\begin{tabular}{@{}llll@{}}
|
\begin{tabular}{@{}llll@{}}
|
||||||
@@ -221,10 +241,10 @@ In this analysis, a subset of runs from \numrange{2808}{2873} with the
|
|||||||
\begin{itemize}
|
\begin{itemize}
|
||||||
\item it was easier to stop and adjust the muon stopping distribution in
|
\item it was easier to stop and adjust the muon stopping distribution in
|
||||||
this thicker target;
|
this thicker target;
|
||||||
\item a thicker target means more stopped muons due to higher muon rate
|
\item a thicker target gives better statistics because of a higher
|
||||||
available at higher momentum and less scattering.
|
muon rate available at a higher momentum and less scattering.
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
Muons momentum of \SI{30.52}{\MeV\per\cc}, 3\%-FWHM spread (scaling factor of
|
Muons with momentum of \SI{30.52}{\MeV\per\cc}, 3\%-FWHM spread (scaling factor of
|
||||||
1.09, normalised to \SI{28}{\MeV\per\cc}) were used for this target after
|
1.09, normalised to \SI{28}{\MeV\per\cc}) were used for this target after
|
||||||
a momentum scanning as described in the next subsection.
|
a momentum scanning as described in the next subsection.
|
||||||
|
|
||||||
@@ -232,8 +252,8 @@ a momentum scanning as described in the next subsection.
|
|||||||
\label{sub:momentum_scan_for_the_100_}
|
\label{sub:momentum_scan_for_the_100_}
|
||||||
Before deciding to use the momentum scaling factor of 1.09, we have scanned
|
Before deciding to use the momentum scaling factor of 1.09, we have scanned
|
||||||
with momentum scales ranging from 1.04 to 1.12 to maximise the
|
with momentum scales ranging from 1.04 to 1.12 to maximise the
|
||||||
observed X-rays rate(and hence maximising the rate of stopped muons). The X-ray
|
observed X-rays rate (and maximising the rate of stopped muons). The X-ray
|
||||||
spectrum at each momentum point was accumulated in more than 30 minutes to
|
spectrum at each momentum point was accumulated in about 30 minutes to
|
||||||
assure a sufficient amount of counts. Details of the scanning runs are listed
|
assure a sufficient amount of counts. Details of the scanning runs are listed
|
||||||
in \cref{tab:al100_scan}.
|
in \cref{tab:al100_scan}.
|
||||||
\begin{table}[htb]
|
\begin{table}[htb]
|
||||||
@@ -259,44 +279,48 @@ in \cref{tab:al100_scan}.
|
|||||||
The on-site quick analysis suggested the 1.09 scaling factor was the
|
The on-site quick analysis suggested the 1.09 scaling factor was the
|
||||||
optimal value so it was chosen for all the runs on this aluminium target. But
|
optimal value so it was chosen for all the runs on this aluminium target. But
|
||||||
the offline analysis later showed that the actual optimal factor was 1.08.
|
the offline analysis later showed that the actual optimal factor was 1.08.
|
||||||
There were two reasons for the mistake:
|
There were two reasons for the discrepancy:
|
||||||
\begin{enumerate}
|
\begin{enumerate}
|
||||||
\item the X-ray rates were normalised to run length, which is biased
|
\item the X-ray rates were normalised to run length, which is biased
|
||||||
since there are more muons available at higher momentum;
|
since there are more muons available at higher momenta;
|
||||||
\item the $(2p-1s)$ peaks of aluminium at \SI{346.828}{\keV} were not
|
\item the $(2p-1s)$ peaks of aluminium at \SI{346.828}{\keV} were not
|
||||||
fitted properly. The peak is interfered by a background peak at
|
fitted properly. The peak is interfered by a background peak at
|
||||||
\SI{351}{\keV} from $^{214}$Pb, but the X-ray peak area was
|
\SI{351}{\keV} from $^{214}$Pb, but the X-ray peak area was
|
||||||
obtained simply by subtracting an automatically estimated background.
|
obtained simply by subtracting an automatically estimated background.
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
In the offline analysis, the X-ray peak and the background peak are fitted by
|
In the offline analysis, the X-ray peak and the background peak are fitted by
|
||||||
two Gaussian peaks on top of a first-order polynomial background. The X-ray peak
|
two Gaussian peaks on top of a linear background. The X-ray peak
|
||||||
area is then normalised to the number of muons hitting the upstream detector
|
area is then normalised to the number of muons hitting the upstream detector
|
||||||
(\cref{fig:al100_xray_fit}).
|
(\cref{fig:al100_xray_fit}).
|
||||||
\begin{figure}[htb]
|
\begin{figure}[htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.47\textwidth]{figs/al100_xray_fit}
|
\includegraphics[width=0.50\textwidth]{figs/al100_xray_fit}
|
||||||
\includegraphics[width=0.47\textwidth]{figs/al100_xray_musc}
|
\includegraphics[width=0.50\textwidth]{figs/al100_xray_musc}
|
||||||
\caption{Fitting of the $(2p-1s)$ muonic X-ray of aluminium and the background
|
\caption{Fitting of the $(2p-1s)$ muonic X-ray of aluminium (red) and the
|
||||||
peak at \SI{351}{\keV} (left). The number of muons is integral of the
|
interfered peak at \SI{351}{\keV} (brown) with a linear background (left).
|
||||||
upstream scintillator spectrum (right) from \numrange{400}{2000} ADC
|
The number of muons is integral of the upstream scintillator spectrum
|
||||||
channels.}
|
(right) from \numrange{400}{2000} ADC channels.}
|
||||||
\label{fig:al100_xray_fit}
|
\label{fig:al100_xray_fit}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
The ratio between the number of X-rays and the number of muons as a function
|
The ratio between the number of X-rays and the number of muons as a function
|
||||||
of momentum scaling factor is plotted on \cref{fig:al100_scan_rate}. The trend
|
of momentum scaling factor is plotted on \cref{fig:al100_scan_rate}. The trend
|
||||||
showed that muons penetrated deeper as the momentum increased, reaching the
|
showed that muons penetrated deeper as the momentum increased, reaching the
|
||||||
optimal value at the scale of 1.08, then decreased as punch through happened
|
optimal value at the scale of 1.08, then decreased as punch through happened
|
||||||
more often from 1.09. The distributions of stopped muons are illustrated by
|
more often from scales of 1.09 and above. The distributions of stopped muons
|
||||||
MC results on the right hand side of \cref{fig:al100_scan_rate}. With the 1.09
|
are illustrated by MC results on the bottom plot in
|
||||||
scale beam, the muons stopped \SI{28}{\um} off-centred to the right silicon arm.
|
\cref{fig:al100_scan_rate}. At the 1.09
|
||||||
\begin{figure}[htb]
|
scale beam, the muons stopped \SI{18}{\um} off-centred to the right silicon
|
||||||
|
arm, the standard deviation of the depth distribution is \SI{29}{\um}.
|
||||||
|
\begin{figure}[!htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.47\textwidth]{figs/al100_scan_rate}
|
\includegraphics[width=0.77\textwidth]{figs/al100_scan_rate}
|
||||||
\includegraphics[width=0.47\textwidth]{figs/al100_mu_stop_mc}
|
\includegraphics[width=0.77\textwidth]{figs/al100_mu_stop_mc}
|
||||||
\caption{Number of X-rays per incoming muon as a function of momentum
|
\caption{Number of X-rays per incoming muon as a function of momentum
|
||||||
scaling factor (left); and muon stopping distributions from MC simulation
|
scaling factor (top); and muon stopping distributions with scaling factors
|
||||||
(right). The depth of muons is measured normal to surface of the target
|
from 1.04 to 1.12 obtained by MC simulation
|
||||||
facing the muon beam.}
|
(bottom). The depth of muon stopping positions are measured normal to
|
||||||
|
the surface of the target facing the muon beam.}
|
||||||
\label{fig:al100_scan_rate}
|
\label{fig:al100_scan_rate}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
@@ -307,24 +331,35 @@ are re-organised into muon events: central muons; and all hits within
|
|||||||
\SI{\pm 10}{\us} from the central muons. The dataset from runs
|
\SI{\pm 10}{\us} from the central muons. The dataset from runs
|
||||||
\numrange{2808}{2873} contains \num{1.17E+9} of such muon events.
|
\numrange{2808}{2873} contains \num{1.17E+9} of such muon events.
|
||||||
|
|
||||||
|
\subsubsection{Particle banding identification}
|
||||||
|
\label{ssub:particle_banding_identification}
|
||||||
|
|
||||||
Selection of proton (and other heavy charged particles) events starts from
|
Selection of proton (and other heavy charged particles) events starts from
|
||||||
searching for muon event that has at least one hit on thick silicon. If there
|
searching for muon event that has at least one hit on thick silicon. If there
|
||||||
is a thin silicon hit within a coincidence window of $\pm 0.5$~\si{\us}\ around
|
is a thin silicon hit within a coincidence window of $\pm 0.5$~\si{\us}\ around
|
||||||
the thick silicon hit, the two hits are considered to belong to one particle.
|
the thick silicon hit, the two hits are considered to belong to one particle.
|
||||||
The specific energy loss spectra recorded by the two silicon arms are plotted
|
The thresholds for energy deposited in all silicon channels, except the thin
|
||||||
on \cref{fig:al100_dedx}.
|
silicon on the left arm, are set at \SI{100}{\keV} in this analysis. The
|
||||||
\begin{figure}[htb]
|
threshold on the left $\Delta E$ counter was higher, at roughly
|
||||||
|
\SI{400}{\keV}, due to higher noise in that channel and it was decided at the
|
||||||
|
run time to rise its threshold to reduce the triggering rate.
|
||||||
|
The specific energy loss as a function of total energy of the charged
|
||||||
|
particles are plotted on \cref{fig:al100_dedx}.
|
||||||
|
\begin{figure}[p]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/al100_dedx}
|
\includegraphics[width=0.85\textwidth]{figs/al100_EdE_left}
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/al100_EdE_right}
|
||||||
\caption{Energy loss in thin silicon detectors as a function of total energy
|
\caption{Energy loss in thin silicon detectors as a function of total energy
|
||||||
recorded by both thin and thick detectors.}
|
recorded by both thin and thick detectors on the left arm (top) and the
|
||||||
|
right arm (bottom).}
|
||||||
\label{fig:al100_dedx}
|
\label{fig:al100_dedx}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
With the aid from MC study (\cref{fig:pid_sim}), the banding on
|
With the aid from MC simulation (\cref{fig:pid_sim}), the banding on
|
||||||
\cref{fig:al100_dedx} can be identified as follows:
|
\cref{fig:al100_dedx} can be identified as follows:
|
||||||
\begin{itemize}
|
\begin{itemize}
|
||||||
\item the densest spot at the lower left conner belonged to electron hits;
|
\item the spot at the lower left conner belonged to electron hits;
|
||||||
\item the small blurry cloud just above the electron region was muon hits;
|
\item the scattered muons formed the small blurry cloud just above the
|
||||||
|
electron region;
|
||||||
\item the most intense band was due to proton hits;
|
\item the most intense band was due to proton hits;
|
||||||
\item the less intense, upper band caused by deuteron hits;
|
\item the less intense, upper band caused by deuteron hits;
|
||||||
\item the highest band corresponded to alpha hits;
|
\item the highest band corresponded to alpha hits;
|
||||||
@@ -332,36 +367,186 @@ With the aid from MC study (\cref{fig:pid_sim}), the banding on
|
|||||||
hits, which is consistent with a relatively low probability of emission of
|
hits, which is consistent with a relatively low probability of emission of
|
||||||
tritons.
|
tritons.
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
|
\begin{figure}[htb]
|
||||||
|
\centering
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/al100_dedx_overlay}
|
||||||
|
\caption{Identifying of charged particles banding: the dots are measured
|
||||||
|
points, the histograms are expected bands of protons (red), deuterons
|
||||||
|
(green) and tritons (blue), respectively. The MC bands are calculated
|
||||||
|
for a pair of 58-\si{\um}-thick and 1535-\si{\um}-thick silicon
|
||||||
|
detectors. The error bars on MC bands show the standard deviation of
|
||||||
|
$\Delta E$ in E respective bins.
|
||||||
|
}
|
||||||
|
\label{fig:dummylabel}
|
||||||
|
\end{figure}
|
||||||
|
|
||||||
The band of protons is then extracted by cut on likelihood probability
|
It is not clearly seen in the $\Delta E-E$ plots because of the rather high
|
||||||
calculated as:
|
thresholds on $\Delta E$, but protons with higher energy would punch through
|
||||||
|
both silicon detectors. Those events have low $\Delta E$ and $E$, making the
|
||||||
|
proton bands to go backward to the origin of the $\Delta E-E$ plots. For the
|
||||||
|
configuration of 58-\si{\um} thin, and 1535-\si{\um} thick detectors, the
|
||||||
|
effect shows up for protons with energy larger than \SI{16}{\MeV}. The
|
||||||
|
returning part of the proton band would make the cut described in
|
||||||
|
the next subsection to include protons with higher energy into lower energy
|
||||||
|
region. The effect of punch through protons could be eliminate using the veto
|
||||||
|
plastic scintillators at the back of each silicon arm. But in this initial
|
||||||
|
analysis, the veto information is not used, therefore the upper limit of
|
||||||
|
proton energy is set at \SI{8}{\MeV} where there is clear separation between
|
||||||
|
the protons at lower and higher energies with the same measured total energy
|
||||||
|
deposition $E$.
|
||||||
|
|
||||||
|
\subsubsection{Proton-like probability cut}
|
||||||
|
\label{ssub:proton_like_probability_cut}
|
||||||
|
Since protons of interested are at low kinetic energy, their $\Delta E$
|
||||||
|
distributions do not have long tails as that of the Landau distribution.
|
||||||
|
For a given $E$, the distribution of $\Delta E$ is more like a Gaussian, and
|
||||||
|
with slightly deformed high energy tail (see \cref{fig:dE_distribution}).
|
||||||
|
|
||||||
|
\begin{figure}[htb]
|
||||||
|
\centering
|
||||||
|
\includegraphics[width=0.75\textwidth]{figs/dE_distribution}
|
||||||
|
\caption{Distributions of $\Delta E$ of protons in a 58-\si{\um}-thick
|
||||||
|
silicon detector for given $E$ in various energy ranges.}
|
||||||
|
\label{fig:dE_distribution}
|
||||||
|
\end{figure}
|
||||||
|
|
||||||
|
%In order to select protons, a proton likelihood probability is defined as:
|
||||||
|
%The band of protons is therefore by cut on likelihood probability
|
||||||
|
%calculated as:
|
||||||
|
For a measured event, a proton likelihood probability is defined as:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
P_{i} = \dfrac{1}{\sqrt{2\pi}\sigma_{\Delta E}}
|
P_{i} = \dfrac{1}{\sqrt{2\pi}\sigma_{\Delta E}}
|
||||||
\exp{\left[\dfrac{(\Delta E_{meas.} - \Delta E_i)^2} {2\sigma^2_{\Delta
|
\exp{\left[\dfrac{(\Delta E_{meas.} - \Delta E_i)^2} {2\sigma^2_{\Delta
|
||||||
E}}\right]}
|
E}}\right]}\,,
|
||||||
\end{equation}
|
\end{equation}
|
||||||
where $\Delta E_{\textrm{meas.}}$ is energy deposition measured by the thin
|
where $\Delta E_{\textrm{meas.}}$ and $E_i$ are measured energy deposition in
|
||||||
silicon detector by a certain proton at energy $E_i$, $\Delta E_i$ and
|
thin silicon detector and in both detectors, respectively; $\Delta E_i$ and
|
||||||
$\sigma_{\Delta E}$ are the expected and standard deviation of the energy loss
|
$\sigma_{\Delta E}$ are the expected value and standard deviation of the energy
|
||||||
caused by the proton calculated by MC study. A threshold is set at \num{1E-4} to
|
loss in the thin detector of protons with energy $E$, calculated by the
|
||||||
extract protons, the resulted band of protons is shown in
|
MC simulation. A measured event with higher $P_i$ is more likely to be
|
||||||
(\cref{fig:al100_protons}).
|
a proton event.
|
||||||
|
|
||||||
|
The lower threshold of proton-like probability, the more protons will be
|
||||||
|
selected, but also more contamination from other charged particles would be
|
||||||
|
classified as protons. The number of protons on the left and right arms at
|
||||||
|
different cuts on $P_i$ are listed in \cref{tab:nprotons_vs_pcut}. The proton
|
||||||
|
yields are integrated in the energy range from \SIrange{2.2}{8}{\MeV}. The
|
||||||
|
lower limit comes from the requirement of having at least one hit on the thick
|
||||||
|
counter. The upper limit is to avoid the inclusion of punch through particles
|
||||||
|
as explained in the previous session.
|
||||||
|
|
||||||
|
The cut efficiency depends on actual shape of the proton spectrum, other
|
||||||
|
charged particles spectra, relative ratio between the yields of different
|
||||||
|
particle species. The fraction of protons missed out, and the fraction of
|
||||||
|
contamination from other charged particles at different probability
|
||||||
|
thresholds, with two different assumptions on spectrum shape: flat distribution
|
||||||
|
and Sobottka and Wills silicon shape (see \eqref{eqn:EH_pdf}),
|
||||||
|
are listed in the four last columns of \cref{tab:nprotons_vs_pcut}. The
|
||||||
|
relative ratio of proton:deuteron:triton:alpha:muon is assumed to be
|
||||||
|
5:2:1:2:2. The probability threshold is therefore chosen to be \num{1.0E-4} in
|
||||||
|
in order to have both relatively low missing and contamination fractions
|
||||||
|
compare to the statistical uncertainty of the measurement. The resulted band of
|
||||||
|
protons is shown in (\cref{fig:al100_protons}).
|
||||||
|
|
||||||
|
\begin{table}[htb]
|
||||||
|
\begin{center}
|
||||||
|
\begin{tabular}{c c c c S S S S}
|
||||||
|
\toprule
|
||||||
|
\textbf{$P_i$} & \textbf{Equiv.} & \multirow{2}{*}{\textbf{Left}} &
|
||||||
|
\multirow{2}{*}{\textbf{Right}} & {\textbf{Miss.}} & \textbf{Contam.}
|
||||||
|
& {\textbf{Miss.}} & \textbf{Contam.}\\
|
||||||
|
|
||||||
|
\textbf{threshold} & \textbf{$\sigma$} & &
|
||||||
|
&{\textbf{flat}} & {\textbf{flat}}
|
||||||
|
&{\textbf{expo.}} & {\textbf{expo.}}\\
|
||||||
|
\midrule
|
||||||
|
\num{4.5E-2} & 2 & 1720 & 2214 & 1.9 \%& 0.03 \%&6.1 \%& 0.06 \%\\
|
||||||
|
\num{2.7E-3} & 3 & 1801 & 2340 & 0.7 \%& 0.05 \%&2.8 \%& 0.1 \%\\
|
||||||
|
\num{1.0E-4} & 3.89 & 1822 & 2373 & 0.5 \%& 0.1 \%&1.2 \%& 0.3 \%\\
|
||||||
|
\num{5.7E-7} & 5 & 1867 & 2421 & 0.4 \%& 0.7 \%&0.7 \%& 0.9 \%\\
|
||||||
|
\bottomrule
|
||||||
|
\end{tabular}
|
||||||
|
\end{center}
|
||||||
|
\caption{Proton yields in energy range from \SIrange{2.2}{8}{\MeV} on the two
|
||||||
|
silicon arms with different thresholds on proton-like probability $P_i$,
|
||||||
|
and the MC calculated missing fractions and contamination levels with two
|
||||||
|
different assumptions on spectrum shape: flatly distributed, and
|
||||||
|
exponential decay spectrum (see \eqref{eqn:EH_pdf}).}
|
||||||
|
\label{tab:nprotons_vs_pcut}
|
||||||
|
\end{table}
|
||||||
|
|
||||||
\begin{figure}[htb]
|
\begin{figure}[htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.47\textwidth]{figs/al100_protons}
|
\includegraphics[width=0.47\textwidth]{figs/al100_protons}
|
||||||
\includegraphics[width=0.47\textwidth]{figs/al100_protons_px_r}
|
\includegraphics[width=0.47\textwidth]{figs/al100_protons_px_r}
|
||||||
\caption{Protons (green) selected using the likelihood probability cut
|
\caption{Protons (green) selected using the likelihood probability cut of
|
||||||
(left). The proton spectrum (right) is obtained by projecting the proton
|
\num{1.0E-4} (left). The proton spectrum (right) is obtained by projecting
|
||||||
band onto the total energy axis.}
|
the proton band onto the total energy axis.}
|
||||||
\label{fig:al100_protons}
|
\label{fig:al100_protons}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
The cut efficiency in the energy range from \SIrange{2}{12}{\MeV} is estimated
|
\subsubsection{Possible backgrounds}
|
||||||
by MC study. The fraction of protons that do not satisfy the probability cut
|
\label{ssub:possible_backgrounds}
|
||||||
is 0.5\%. The number of other charged particles that are misidentified as
|
|
||||||
protons depends on the ratios between those species and protons. Assuming
|
There are several sources of potential backgrounds in this proton measurement:
|
||||||
a proton:deuteron:triton:alpha:muon ratio of 5:2:1:2:2, the number of
|
\begin{enumerate}
|
||||||
misidentified hits is 0.1\% of the number of protons.
|
\item Protons emitted after capture of scattered muons in the lead
|
||||||
|
shield: the incoming muons could be scattered to other materials
|
||||||
|
surrounding the target, emitting protons to the silicon detectors. In
|
||||||
|
order to avoid complication of estimating this background, we used lead
|
||||||
|
sheets to collimate and shield around the target and detectors. If
|
||||||
|
a scattered muon is captured by the lead shielding, the proton from lead
|
||||||
|
would be emitted shortly after the muon hit because of the short average
|
||||||
|
lifetime of muons in lead (\SI{78.4}{\ns}~\cite{Measday.2001}). In
|
||||||
|
comparison, average lifetime of muons in aluminium is
|
||||||
|
\SI{864}{\ns}~\cite{Measday.2001}, therefore a simple cut in timing could
|
||||||
|
eliminate background of this kind.\\
|
||||||
|
The timing of events classified as protons are plotted in
|
||||||
|
\cref{fig:al100_proton_timing}. The spectra show no significant fast
|
||||||
|
decaying component, which should show up if the background from lead
|
||||||
|
shielding were sizeable. A fit of an exponential function on top of a flat
|
||||||
|
background gives the average lifetimes of muons as:
|
||||||
|
\begin{align}
|
||||||
|
\tau_{\textrm{left}} &= \SI{870 \pm 25}{\ns} \,,\\
|
||||||
|
\tau_{\textrm{right}} &= \SI{868 \pm 21}{\ns} \,.
|
||||||
|
\end{align}
|
||||||
|
|
||||||
|
\begin{figure}[htb]
|
||||||
|
\centering
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/al100_proton_timing}
|
||||||
|
\caption{Timing of protons relative to muon hit. The spectra show the
|
||||||
|
characteristic one-component decay shape.}
|
||||||
|
\label{fig:al100_proton_timing}
|
||||||
|
\end{figure}
|
||||||
|
The consistency between fitted lifetimes and the reference value of average
|
||||||
|
lifetime of muons in aluminium at \SI{864\pm 2}{\ns} suggests the background
|
||||||
|
from the lead shielding is negligible. This smallness can be explained as
|
||||||
|
a combination of the two facts: (i) only
|
||||||
|
a minority fraction of muons punched through the target and reached the
|
||||||
|
downstream lead shield as illustrated in
|
||||||
|
\cref{fig:al100_scan_rate}; and (ii) the probability of emitting protons from
|
||||||
|
lead is very low compare to that of aluminium, about 0.4\% per
|
||||||
|
capture (see \cref{tab:lifshitzsinger_cal_proton_rate}).
|
||||||
|
|
||||||
|
\item The protons emitted after scattered muons stopped at the surface of
|
||||||
|
the thin silicon detectors: these protons could mimic the signal if they
|
||||||
|
appear within \SI{1}{\us} around the time muon hit the upstream counter.
|
||||||
|
The $\Delta E$ and $E$ in this case would be sum of energy of a muon and
|
||||||
|
energy of the resulted proton. The average energy of scattered muons can be
|
||||||
|
seen in \cref{fig:al100_dedx} to be about \SI{1.4}{\MeV}. The measured
|
||||||
|
$\Delta E$ and $E$ then would be shifted by \SI{1.4}{\MeV}, makes the
|
||||||
|
measured data point move far away from the expected proton band. Therefore
|
||||||
|
this kind of background should be small with the current probability cut.
|
||||||
|
|
||||||
|
\item The random background: this kind of background can be
|
||||||
|
examined by the same timing spectrum in
|
||||||
|
\cref{fig:al100_proton_timing}. The random events show up at negative time
|
||||||
|
difference and large delay time regions and give a negligible contribution
|
||||||
|
to the total number of protons.
|
||||||
|
\end{enumerate}
|
||||||
|
|
||||||
|
It is concluded from above arguments that the backgrounds of this proton
|
||||||
|
measurement is negligibly small.
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||||
\section{Proton emission rate from aluminium}
|
\section{Proton emission rate from aluminium}
|
||||||
\label{sec:proton_emission_rate_from_aluminium}
|
\label{sec:proton_emission_rate_from_aluminium}
|
||||||
@@ -376,8 +561,8 @@ of protons is normalised to the number of nuclear muon captures.
|
|||||||
The numbers of protons in the energy range from \SIrange{2.2}{8.5}{\MeV} after
|
The numbers of protons in the energy range from \SIrange{2.2}{8.5}{\MeV} after
|
||||||
applying the probability cut are:
|
applying the probability cut are:
|
||||||
\begin{align}
|
\begin{align}
|
||||||
N_{\textrm{p meas. left}} = 1822\\% \pm 42.7\\
|
N_{\textrm{p meas. left}} = 1822 \pm 42.7 \,,\\
|
||||||
N_{\textrm{p meas. right}} = 2373% \pm 48.7
|
N_{\textrm{p meas. right}} = 2373 \pm 48.7 \,.
|
||||||
\end{align}
|
\end{align}
|
||||||
The right arm received significantly more protons than the left arm did, which
|
The right arm received significantly more protons than the left arm did, which
|
||||||
is expected as in \cref{sub:momentum_scan_for_the_100_} where it is shown that
|
is expected as in \cref{sub:momentum_scan_for_the_100_} where it is shown that
|
||||||
@@ -405,15 +590,18 @@ the parameters of the initial protons are:
|
|||||||
the upstream face of the target;
|
the upstream face of the target;
|
||||||
\item energy: flatly distributed from \SIrange{1.5}{15}{\MeV}.
|
\item energy: flatly distributed from \SIrange{1.5}{15}{\MeV}.
|
||||||
\end{itemize}
|
\end{itemize}
|
||||||
The resulting response matrices for the two arms are presented in
|
The calculated response matrices for the two arms are presented in
|
||||||
\cref{fig:al100_resp_matrices}. These are then used as MC truth to train and
|
\cref{fig:al100_resp_matrices}. The different path lengths inside the target
|
||||||
test the unfolding code. The code uses an existing ROOT package
|
to the two silicon arms causes the difference in the two matrices. The
|
||||||
called RooUnfold~\cite{Adye.2011} where the iterative Bayesian unfolding
|
response matrices are then used as MC truth to train and test the unfolding
|
||||||
method is implemented.
|
code. The code uses an existing ROOT package called RooUnfold~\cite{Adye.2011}
|
||||||
|
where the iterative Bayesian unfolding method is implemented.
|
||||||
\begin{figure}[htb]
|
\begin{figure}[htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.85\textwidth]{./figs/al100_resp}
|
\includegraphics[width=0.99\textwidth]{./figs/al100_resp}
|
||||||
\caption{Response functions for the two silicon arms.}
|
\caption{Response functions for the two silicon arms, showing the relation
|
||||||
|
between protons energy at birth and as detected by the silicon detector
|
||||||
|
arms.}
|
||||||
\label{fig:al100_resp_matrices}
|
\label{fig:al100_resp_matrices}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
%After training, the unfolding code is applied on the measured spectra from the
|
%After training, the unfolding code is applied on the measured spectra from the
|
||||||
@@ -425,15 +613,18 @@ method is implemented.
|
|||||||
%which is \SI{4.1}{\MeV} for protons emitted from $^{27}$Mg.
|
%which is \SI{4.1}{\MeV} for protons emitted from $^{27}$Mg.
|
||||||
The unfolded spectra using the two observed spectra at the two arms as input
|
The unfolded spectra using the two observed spectra at the two arms as input
|
||||||
are shown in \cref{fig:al100_unfold}. The two unfolded spectra generally agree
|
are shown in \cref{fig:al100_unfold}. The two unfolded spectra generally agree
|
||||||
with each other, except for a few first and last bins. The discrepancy and
|
with each other, except for a few first and last bins.
|
||||||
large uncertainties at the low energy region are because of only a small
|
In the lower energy region, there is a small probability for such protons to
|
||||||
number of protons with those energies could reach the detectors. The jump on
|
escape and reach the detectors, therefore the unfolding is generally unstable
|
||||||
the right arm at around \SI{9}{\MeV} can be explained as the punch-through
|
and the uncertainties are large.
|
||||||
protons were counted as the proton veto counters were not used in this
|
At the higher end, the jump on the right arm at around \SI{9}{\MeV} can be
|
||||||
analysis.
|
explained as the punch-through protons were counted as the proton veto counters
|
||||||
\begin{figure}[htb]
|
were not used in this analysis. The lower threshold on the thin silicon
|
||||||
|
detector at the right arm compared with that at the left arm makes this
|
||||||
|
misidentification worse.
|
||||||
|
\begin{figure}[!htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/al100_unfolded_lr}
|
\includegraphics[width=0.80\textwidth]{figs/al100_unfolded_lr}
|
||||||
\caption{Unfolded proton spectra from the 100-\si{\um} aluminium target.}
|
\caption{Unfolded proton spectra from the 100-\si{\um} aluminium target.}
|
||||||
\label{fig:al100_unfold}
|
\label{fig:al100_unfold}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
@@ -445,27 +636,37 @@ analysis.
|
|||||||
%\item comparison between the two arms;
|
%\item comparison between the two arms;
|
||||||
%\item and unfolding of a MC-generated spectrum.
|
%\item and unfolding of a MC-generated spectrum.
|
||||||
%\end{itemize}
|
%\end{itemize}
|
||||||
The stability of the unfolding code is tested by varying the lower cut-off
|
The stability of the unfolding code is tested by varying the lower and upper
|
||||||
energy of the input spectrum. \cref{fig:al100_cutoff_study} show that the
|
cut-off energies of the input spectrum. Plots in \cref{fig:al100_cutoff_study}
|
||||||
shapes of the unfolded spectra are stable. The lower cut-off energy of the
|
show that the shapes of the unfolded spectra are stable after a few first or
|
||||||
output increases as that of the input increases, and the shape is generally
|
last bins.
|
||||||
unchanged after a few bins.
|
%The
|
||||||
\begin{figure}[htb]
|
%lower cut-off energy of the
|
||||||
|
%output increases as that of the input increases, and the shape is generally
|
||||||
|
%unchanged after a few bins.
|
||||||
|
\begin{figure}[!htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/al100_cutoff_study}
|
\includegraphics[width=0.85\textwidth]{figs/al100_cutoff_study}
|
||||||
\caption{Unfolded spectra with different cut-off energies.}
|
\includegraphics[width=0.85\textwidth]{figs/al100_up_cut_off_reco}
|
||||||
|
\caption{Unfolded spectra with different lower (top) and upper (bottom)
|
||||||
|
cut-off energies.}
|
||||||
\label{fig:al100_cutoff_study}
|
\label{fig:al100_cutoff_study}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
The proton yields calculated from observed spectra in two arms are compared in
|
The proton yields calculated from observed spectra in two arms are compared in
|
||||||
\cref{fig:al100_integral_comparison} where the upper limit of the integrals
|
\cref{fig:al100_integral_comparison} where the upper limit of the integrals
|
||||||
is fixed at \SI{8}{\MeV}, and the lower limit is varied in \SI{400}{\keV} step.
|
is fixed at \SI{8}{\MeV}, and the lower limit is varied in \SI{400}{\keV}
|
||||||
The difference is large at cut-off energies less than \SI{4}{\MeV} due to
|
step. The upper limit was chosen to avoid the effects of punched through
|
||||||
large uncertainties at the first bins. Above \SI{4}{\MeV}, the two arms show
|
protons. The difference is large at cut-off energies less than \SI{4}{\MeV}
|
||||||
consistent numbers of protons.
|
due to large uncertainties at the first bins. Above \SI{4}{\MeV}, the two arms
|
||||||
|
show consistent numbers of protons.
|
||||||
\begin{figure}[htb]
|
\begin{figure}[htb]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/al100_integral_comparison}
|
\includegraphics[width=0.85\textwidth]{figs/al100_integral_comparison}
|
||||||
\caption{Proton yields calculated from two arms.}
|
\caption{Proton yields calculated from two arms. The upper limit of
|
||||||
|
integrations is fixed at \SI{8}{\MeV}, the horizontal axis is the lower
|
||||||
|
limit of the integrations. The proton yields on the two arm agree well
|
||||||
|
with each other from above \SI{4}{\MeV}.}
|
||||||
\label{fig:al100_integral_comparison}
|
\label{fig:al100_integral_comparison}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
The yields of protons from \SIrange{4}{8}{\MeV} are:
|
The yields of protons from \SIrange{4}{8}{\MeV} are:
|
||||||
@@ -490,13 +691,13 @@ The number of emitted protons is taken as average of the two yields:
|
|||||||
|
|
||||||
%The X-ray spectrum on the germanium detector is shown on
|
%The X-ray spectrum on the germanium detector is shown on
|
||||||
%\cref{fig:al100_ge_spec}.
|
%\cref{fig:al100_ge_spec}.
|
||||||
Fitting the double peaks on top of a first-order
|
Fitting the double peaks on top of a linear background
|
||||||
polynomial gives the X-ray peak area of $5903.5 \pm 109.2$. With the same
|
gives the X-ray peak area of $5903.5 \pm 109.2$. With the same
|
||||||
procedure as in the case of the active target, the number stopped muons and
|
procedure as in the case of the active target, the number stopped muons and
|
||||||
the number of nuclear captures are:
|
the number of nuclear captures are:
|
||||||
\begin{align}
|
\begin{align}
|
||||||
N_{\mu \textrm{ stopped}} &= (1.57 \pm 0.05)\times 10^7\\
|
N_{\mu \textrm{ stopped}} &= (1.57 \pm 0.05)\times 10^7\,,\\
|
||||||
N_{\mu \textrm{ nucl. cap.}} &= (9.57\pm 0.31)\times 10^6
|
N_{\mu \textrm{ nucl. cap.}} &= (9.57\pm 0.31)\times 10^6\,.
|
||||||
\end{align}
|
\end{align}
|
||||||
|
|
||||||
\subsection{Proton emission rate}
|
\subsection{Proton emission rate}
|
||||||
@@ -504,7 +705,7 @@ the number of nuclear captures are:
|
|||||||
The proton emission rate in the range from \SIrange{4}{8}{\MeV} is therefore:
|
The proton emission rate in the range from \SIrange{4}{8}{\MeV} is therefore:
|
||||||
\begin{equation}
|
\begin{equation}
|
||||||
R_{\textrm{p}} = \frac{169.3\times 10^3}{9.57\times 10^6} = 1.7\times
|
R_{\textrm{p}} = \frac{169.3\times 10^3}{9.57\times 10^6} = 1.7\times
|
||||||
10^{-2}
|
10^{-2}\,.
|
||||||
\label{eq:proton_rate_al}
|
\label{eq:proton_rate_al}
|
||||||
\end{equation}
|
\end{equation}
|
||||||
|
|
||||||
@@ -514,9 +715,9 @@ with the same parameterisation as in \eqref{eqn:EH_pdf}. The
|
|||||||
falling edge. The falling edge has only one decay component and is suitable to
|
falling edge. The falling edge has only one decay component and is suitable to
|
||||||
describe the proton spectrum with the equilibrium emission only assumption.
|
describe the proton spectrum with the equilibrium emission only assumption.
|
||||||
The pre-equilibrium emission contribution should be small for low-$Z$ material,
|
The pre-equilibrium emission contribution should be small for low-$Z$ material,
|
||||||
for aluminium the contribution of this component is 2.2\% according to
|
for aluminium the contribution of this component is 2.2\% of total number of
|
||||||
Lifshitz and Singer~\cite{LifshitzSinger.1980}.
|
protons according to Lifshitz and Singer~\cite{LifshitzSinger.1980}.
|
||||||
|
%%TODO: draw the function and integral
|
||||||
The fitted results
|
The fitted results
|
||||||
are shown in \cref{fig:al100_parameterisation} and \cref{tab:al100_fit_pars}.
|
are shown in \cref{fig:al100_parameterisation} and \cref{tab:al100_fit_pars}.
|
||||||
The average spectrum is obtained by taking the average of the two unfolded
|
The average spectrum is obtained by taking the average of the two unfolded
|
||||||
@@ -526,10 +727,16 @@ with each other within their errors.
|
|||||||
Using the fitted parameters of the average spectrum, the integration in range
|
Using the fitted parameters of the average spectrum, the integration in range
|
||||||
from \SIrange{4}{8}{\MeV} is 51\% of the total number of
|
from \SIrange{4}{8}{\MeV} is 51\% of the total number of
|
||||||
protons. The total proton emission rate is therefore estimated to be $3.5\times 10^{-2}$.
|
protons. The total proton emission rate is therefore estimated to be $3.5\times 10^{-2}$.
|
||||||
\begin{figure}[htb]
|
\begin{figure}[!p]
|
||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.85\textwidth]{figs/al100_parameterisation}
|
\includegraphics[width=0.85\textwidth]{figs/al100_parameterisation}
|
||||||
\caption{Fitting of the unfolded spectra.}
|
\includegraphics[width=0.85\textwidth]{figs/al100_fit_avgspec}
|
||||||
|
\includegraphics[width=0.85\textwidth]{figs/al100_fitted_func_integral}
|
||||||
|
\caption{Fitting of the unfolded spectra on the left and right arms (top),
|
||||||
|
and on the average spectrum (middle). The bottom plot shows the fitted
|
||||||
|
function of the average spectrum in the energy range from
|
||||||
|
\SIrange{1}{50}{\MeV}. The proton yield in the region from
|
||||||
|
\SIrange{4}{8}{\MeV} (shaded) is 51\% of the whole spectral integral.}
|
||||||
\label{fig:al100_parameterisation}
|
\label{fig:al100_parameterisation}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
|
|
||||||
@@ -587,9 +794,13 @@ The last item is studied by MC method using the parameterisation in
|
|||||||
\centering
|
\centering
|
||||||
\includegraphics[width=0.48\textwidth]{figs/al100_MCvsUnfold}
|
\includegraphics[width=0.48\textwidth]{figs/al100_MCvsUnfold}
|
||||||
\includegraphics[width=0.48\textwidth]{figs/al100_unfold_truth_ratio}
|
\includegraphics[width=0.48\textwidth]{figs/al100_unfold_truth_ratio}
|
||||||
\caption{Comparison between an unfolded spectrum and MC truth: spectra
|
\caption{Comparison between an unfolded spectrum and MC truth. On the left
|
||||||
(left), and yields (right). The ratio is defined as $\textrm{(Unfold - MC
|
hand side, the solid, red line is MC truth, the blue histogram is the
|
||||||
truth)/(MC truth)}$}
|
unfoldede spectrum. The ratio between the two yields is compared in the
|
||||||
|
right hand side plot with the upper end of integration is fixed at
|
||||||
|
\SI{8}{\MeV}, and a moving lower end of integration. The discrepancy
|
||||||
|
is genenerally smaller than 5\% if the lower end energy is smaller than
|
||||||
|
\SI{6}{\MeV}.}
|
||||||
\label{fig:al100_MCvsUnfold}
|
\label{fig:al100_MCvsUnfold}
|
||||||
\end{figure}
|
\end{figure}
|
||||||
\Cref{fig:al100_MCvsUnfold} shows that the yield obtained after unfolding is
|
\Cref{fig:al100_MCvsUnfold} shows that the yield obtained after unfolding is
|
||||||
@@ -608,7 +819,7 @@ presented in \cref{tab:al100_uncertainties_all}.
|
|||||||
Number of muons & 3.2\% \\
|
Number of muons & 3.2\% \\
|
||||||
Statistical from measured spectra & 1.1\% \\
|
Statistical from measured spectra & 1.1\% \\
|
||||||
Systematic from unfolding & 5.0\% \\
|
Systematic from unfolding & 5.0\% \\
|
||||||
Systematic from PID & \textless0.5\% \\
|
Systematic from PID & \textless1.0\% \\
|
||||||
\midrule
|
\midrule
|
||||||
Total & 6.1\%\\
|
Total & 6.1\%\\
|
||||||
\bottomrule
|
\bottomrule
|
||||||
@@ -649,13 +860,7 @@ validated:
|
|||||||
The proton emission spectrum in \cref{sub:proton_emission_rate} peaks around
|
The proton emission spectrum in \cref{sub:proton_emission_rate} peaks around
|
||||||
\SI{3.7}{\MeV} which is a little below the Coulomb barrier for proton of
|
\SI{3.7}{\MeV} which is a little below the Coulomb barrier for proton of
|
||||||
\SI{3.9}{\MeV} calculated using \eqref{eqn:classical_coulomb_barrier}. The
|
\SI{3.9}{\MeV} calculated using \eqref{eqn:classical_coulomb_barrier}. The
|
||||||
spectrum has a decay constant of \SI{2.6}{\MeV} in higher energy region,
|
spectrum has a decay constant of \SI{2.6}{\MeV} in higher energy region.
|
||||||
makes the emission probability drop more quickly than silicon charged
|
|
||||||
particles spectrum of Sobottka and Wills~\cite{SobottkaWills.1968} where the
|
|
||||||
decay constant was \SI{4.6}{\MeV}. This can be explained as the silicon
|
|
||||||
spectrum includes other heavier particles which have higher Coulomb barriers,
|
|
||||||
hence contribute more in the higher energy bins, effectively reduces the decay
|
|
||||||
rate.
|
|
||||||
|
|
||||||
The partial emission rate measured in the energy range from
|
The partial emission rate measured in the energy range from
|
||||||
\SIrange{4}{8}{\MeV} is:
|
\SIrange{4}{8}{\MeV} is:
|
||||||
@@ -717,4 +922,16 @@ nucleus and less stable than that from aluminium, $^{27}$Mg. The proton
|
|||||||
separation energy for $^{28}$Al is \SI{9.6}{\MeV}, which is significantly
|
separation energy for $^{28}$Al is \SI{9.6}{\MeV}, which is significantly
|
||||||
lower than that of $^{27}$Mg at \SI{15.0}{\MeV}~\cite{AudiWapstra.etal.2003}.
|
lower than that of $^{27}$Mg at \SI{15.0}{\MeV}~\cite{AudiWapstra.etal.2003}.
|
||||||
|
|
||||||
|
The proton spectrum from aluminium is softer than silicon charged
|
||||||
|
particles spectrum of Sobottka and Wills~\cite{SobottkaWills.1968} where the
|
||||||
|
decay constant was \SI{4.6}{\MeV}. Two possible reasons can explain this
|
||||||
|
difference in shape:
|
||||||
|
\begin{enumerate}
|
||||||
|
\item The higher proton separation energy of $^{27}$Mg gives less
|
||||||
|
phase space for protons at higher energies than that in the case of
|
||||||
|
$^{28}$Al if the excitation energies of the two compound nuclei are similar.
|
||||||
|
\item The silicon spectrum includes other heavier
|
||||||
|
particles which have higher Coulomb barriers, hence contribute more in the
|
||||||
|
higher energy bins, effectively reduces the decay rate.
|
||||||
|
\end{enumerate}
|
||||||
|
|
||||||
|
|||||||
@@ -1,12 +1,11 @@
|
|||||||
\chapter{Discussions on the impact to the COMET Phase-I}
|
\chapter{Impact to the COMET Phase-I}
|
||||||
\label{cha:discussions_on_the_impact_to_the_comet_phase_i}
|
\label{cha:discussions_on_the_impact_to_the_comet_phase_i}
|
||||||
The measured proton emission rate of 3.5\% is about 5 times
|
The measured proton emission rate of 3.5\% is about 5 times
|
||||||
smaller than the figure using to make the baseline design of the CDC in COMET
|
smaller than the figure using to make the baseline design of the CDC in COMET
|
||||||
Phase-I. The spectrum shape
|
Phase-I. The spectrum shape is softer than that of silicon,
|
||||||
peaks around \SI{4}{\MeV} rather than at \SI{2.5}{\MeV}, and decays more
|
peaks around \SI{4}{\MeV} rather than at \SI{2.5}{\MeV}
|
||||||
quickly in compared with the silicon spectrum(\cref{fig:sobottka_spec}).
|
(\cref{fig:sobottka_spec}). Therefore CDC hit rate due to proton should be
|
||||||
Therefore CDC hit rate due to proton should be smaller than the current
|
smaller than the current estimation.
|
||||||
estimation.
|
|
||||||
|
|
||||||
The CDC proton hit rate is calculated by a toy MC study. The dimensions of the
|
The CDC proton hit rate is calculated by a toy MC study. The dimensions of the
|
||||||
geometry shown in \cref{fig:cdc_toy_mc} are from \cref{ssub:CDC_configuration}.
|
geometry shown in \cref{fig:cdc_toy_mc} are from \cref{ssub:CDC_configuration}.
|
||||||
@@ -54,54 +53,31 @@ A muon stopping rate of \SI{1.3E9}{\Hz} is assumed as in the COMET Phase I's
|
|||||||
TDR. The number of proton emitted is then $\num{1.3E9} \times 0.609 \times
|
TDR. The number of proton emitted is then $\num{1.3E9} \times 0.609 \times
|
||||||
0.035 = \SI{2.8E7}{\Hz}$. The hit rates on a single cell in the inner most
|
0.035 = \SI{2.8E7}{\Hz}$. The hit rates on a single cell in the inner most
|
||||||
layer due to these protons with
|
layer due to these protons with
|
||||||
different absorber thickness are shown in \cref{tab:proton_cdc_hitrate}.
|
different absorber configurations are listed in
|
||||||
|
\cref{tab:proton_cdc_hitrate_comp}.
|
||||||
|
|
||||||
\begin{table}[htb]
|
\begin{table}[htb]
|
||||||
\begin{center}
|
\begin{center}
|
||||||
\begin{tabular}{S S S S S S}
|
\begin{tabular}{S S S S S}
|
||||||
\toprule
|
\toprule
|
||||||
{\textbf{Absorber}} &{\textbf{Inner wall}} & {\textbf{Total CFRP}}&
|
{\textbf{Absorber}} &{\textbf{Inner wall}} & {\textbf{Total CFRP}}&
|
||||||
{\textbf{Proton}} & {\textbf{Momentum}} & {\textbf{Integrated charge}}\\
|
{\textbf{Proton hit rate}} & {\textbf{Proton hit rate}}\\
|
||||||
{\textbf{thickness}} &{\textbf{thickness}} & {\textbf{thickness}}&
|
{\textbf{thickness}} &{\textbf{thickness}} & {\textbf{thickness}}&
|
||||||
{\textbf{hit rate}} &{\textbf{spread $\Delta p$}} &{\textbf{300 days}}\\
|
{\textbf{Phase-I TDR}} & {\textbf{New estimation}}\\
|
||||||
{(\si{\mm})} & {(\si{\mm})} & {(\si{\mm})} & {(\si{\Hz})}
|
{(\si{\mm})} & {(\si{\mm})} & {(\si{\mm})} & {(\si{\Hz})}& {(\si{\Hz})}\\
|
||||||
& {(\si{\keV\per\cc)}} &{(mC/cm)}\\
|
|
||||||
\midrule
|
\midrule
|
||||||
1 &0.5&1.5 & 2 & 195 & 25\\
|
1 &0.5&1.5 & 4E+3 & 2 \\
|
||||||
0.5 &0.5&1.0 & 126 & 167 & 60\\
|
0.5 &0.5&1.0 & 11E+3& 126 \\
|
||||||
0 &0.5&0.5 & 1436 & 133 & 160\\
|
0 &0.5&0.5 & 30E+3& 1436 \\
|
||||||
%0 &0.3&0.3 & 8281 & {-} & {-}\\
|
|
||||||
%0 &0.1&0.1 & 15011& {-} & {-}\\
|
|
||||||
\bottomrule
|
\bottomrule
|
||||||
\end{tabular}
|
\end{tabular}
|
||||||
\end{center}
|
\end{center}
|
||||||
\caption{CDC proton hit rates at different configuration of proton absorber
|
\caption{CDC proton hit rates in this study in comparison with the expected
|
||||||
and inner wall. The momentum spreads for \SI{0.5}{\mm} thick inner wall are
|
rates in COMET Phase-I's Technical Design Report~\cite{COMET.2014} at
|
||||||
taken from \cref{tab:comet_absorber_impact}.}
|
different configurations of proton absorber and inner wall.}
|
||||||
\label{tab:proton_cdc_hitrate}
|
\label{tab:proton_cdc_hitrate_comp}
|
||||||
\end{table}
|
\end{table}
|
||||||
|
|
||||||
%\begin{table}[htb]
|
|
||||||
%\begin{center}
|
|
||||||
%\begin{tabular}{S S S S S}
|
|
||||||
%\toprule
|
|
||||||
%{\textbf{Absorber}} &{\textbf{Inner wall}} & {\textbf{Total CFRP}}&
|
|
||||||
%{\textbf{Proton hit rate}} & {\textbf{Proton hit rate}}\\
|
|
||||||
%{\textbf{thickness}} &{\textbf{thickness}} & {\textbf{thickness}}&
|
|
||||||
%{\textbf{Phase-I TDR}} & {\textbf{New estimation}}\\
|
|
||||||
%{(\si{\mm})} & {(\si{\mm})} & {(\si{\mm})} & {(\si{\Hz})}& {(\si{\Hz})}\\
|
|
||||||
%\midrule
|
|
||||||
%1 &0.5&1.5 & 4E+3 & 2 \\
|
|
||||||
%0.5 &0.5&1.0 & 11E+3& 126 \\
|
|
||||||
%0 &0.5&0.5 & 30E+3& 1436 \\
|
|
||||||
%\bottomrule
|
|
||||||
%\end{tabular}
|
|
||||||
%\end{center}
|
|
||||||
%\caption{CDC proton hit rates at different configuration of proton absorber
|
|
||||||
%and inner wall. The momentum spreads for \SI{0.5}{\mm} thick inner wall are
|
|
||||||
%taken from \cref{tab:comet_absorber_impact}.}
|
|
||||||
%\label{tab:proton_cdc_hitrate}
|
|
||||||
%\end{table}
|
|
||||||
|
|
||||||
%\begin{table}[htb]
|
%\begin{table}[htb]
|
||||||
%\begin{center}
|
%\begin{center}
|
||||||
%\begin{tabular}{S S S S S S}
|
%\begin{tabular}{S S S S S S}
|
||||||
@@ -121,19 +97,57 @@ different absorber thickness are shown in \cref{tab:proton_cdc_hitrate}.
|
|||||||
%taken from \cref{tab:comet_absorber_impact}.}
|
%taken from \cref{tab:comet_absorber_impact}.}
|
||||||
%\end{table}
|
%\end{table}
|
||||||
At the baseline design of \SI{0.5}{\mm}, the hit rate is only \SI{126}{\Hz},
|
At the baseline design of \SI{0.5}{\mm}, the hit rate is only \SI{126}{\Hz},
|
||||||
much smaller than the current estimation at \SI{34}{\kHz}. Even without the
|
much smaller than the current estimation at \SI{11}{\kHz}. Even without the
|
||||||
absorber, proton hit rate remains low at \SI{1.4}{\kHz}.
|
absorber, proton hit rate remains lower than that level at \SI{1.4}{\kHz}.
|
||||||
|
Therefore the absorber is not necessary as far as the hit rate is concerned.
|
||||||
%Therefore a proton
|
%Therefore a proton
|
||||||
%absorber is not needed for the COMET Phase I's CDC.
|
%absorber is not needed for the COMET Phase I's CDC.
|
||||||
|
|
||||||
If the proton absorber is not used, the momentum spread of the signal electron
|
If the proton absorber is not used, the momentum spread of the signal electron
|
||||||
reduces from \SI{167}{\keV} to \SI{131}{\keV}. In case a lower momentum spread
|
reduces from \SI{167}{\keV\per\cc} to \SI{131}{\keV\per\cc} (\cref{tab:proton_cdc_hitrate}).
|
||||||
is desired, it is possible to reduce the thickness of the inner wall. The last
|
This is a small improvement since the momentum resolution is dominated by
|
||||||
two rows of \cref{tab:proton_cdc_hitrate} show that even with thinner walls at
|
intrinsic spread of \SI{197}{\keV\per\cc} due to multiple scattering in gas
|
||||||
\SI{0.3}{\mm} and \SI{0.1}{\mm} the hit rate by protons are still at
|
and wires.
|
||||||
manageable levels. However, reducing the wall thickness would be governed by
|
|
||||||
other requirements such as mechanical structure and gas-tightness.
|
|
||||||
|
|
||||||
|
The last column of \cref{tab:proton_cdc_hitrate} shows the integrated charge
|
||||||
|
per unit length of a wire. The TDR deems an integrated charge level of
|
||||||
|
\SI{200}{\milli\coulomb\per\cm} safe. So even with the pessimistic estimation using
|
||||||
|
silicon rate and spectrum and without the proton absorber, the integrated
|
||||||
|
charge level in the CDC is still below the requirement. Therefore removing the
|
||||||
|
absorber will not worsen the ageing process of the wires.
|
||||||
|
\begin{table}[htb]
|
||||||
|
\begin{center}
|
||||||
|
\begin{tabular}{S S S S S}
|
||||||
|
\toprule
|
||||||
|
{\textbf{Absorber}} &{\textbf{Inner wall}} & {\textbf{Total CFRP}}&
|
||||||
|
{\textbf{Momentum}} & {\textbf{Integrated charge}}\\
|
||||||
|
{\textbf{thickness}} &{\textbf{thickness}} & {\textbf{thickness}}&
|
||||||
|
{\textbf{spread $\Delta p$}} &{\textbf{300 days}}\\
|
||||||
|
{(\si{\mm})} & {(\si{\mm})} & {(\si{\mm})}
|
||||||
|
& {(\si{\keV\per\cc)}} &{(mC/cm)}\\
|
||||||
|
\midrule
|
||||||
|
1 &0.5&1.5 & 195 & 25\\
|
||||||
|
0.5 &0.5&1.0 & 167 & 60\\
|
||||||
|
0 &0.5&0.5 & 133 & 160\\
|
||||||
|
%0 &0.3&0.3 & 8281 & {-} & {-}\\
|
||||||
|
%0 &0.1&0.1 & 15011& {-} & {-}\\
|
||||||
|
\bottomrule
|
||||||
|
\end{tabular}
|
||||||
|
\end{center}
|
||||||
|
\caption{Momentum spreads due to the inner wall and absorber, and integrated
|
||||||
|
charge per unit length of wire as calculated in the COMET Phase-I's TDR.
|
||||||
|
The momentum spreads were calculated for signal electrons at
|
||||||
|
\SI{104.96}{\MeV\per\cc}. The integrated charge is estimated assuming 300
|
||||||
|
days of operation.}
|
||||||
|
\label{tab:proton_cdc_hitrate}
|
||||||
|
\end{table}
|
||||||
|
|
||||||
|
%In case a lower momentum spread is desired, it is possible to reduce the
|
||||||
|
%thickness of the inner wall. The last
|
||||||
|
%two rows of \cref{tab:proton_cdc_hitrate} show that even with thinner walls at
|
||||||
|
%\SI{0.3}{\mm} and \SI{0.1}{\mm} the hit rate by protons are still at
|
||||||
|
%manageable levels. However, reducing the wall thickness would be governed by
|
||||||
|
%other requirements such as mechanical structure and gas-tightness.
|
||||||
In summary, the toy MC study with the preliminary proton rate and spectrum
|
In summary, the toy MC study with the preliminary proton rate and spectrum
|
||||||
shows that a proton absorber is not needed. It confirms the known fact that the
|
shows that a proton absorber is not needed. It confirms the known fact that the
|
||||||
estimation used in COMET Phase-I is conservative, and provides a solid
|
estimation used in COMET Phase-I is conservative, and provides a solid
|
||||||
|
|||||||
@@ -22,20 +22,26 @@ was made. The main results are:
|
|||||||
\item obtaining preliminary results on proton emission rate and spectrum:
|
\item obtaining preliminary results on proton emission rate and spectrum:
|
||||||
the proton spectrum has a peak at \SI{3.7}{\MeV}, then reduces exponentially
|
the proton spectrum has a peak at \SI{3.7}{\MeV}, then reduces exponentially
|
||||||
with a decay constant of \SI{2.6}{\MeV}. The partial emission rate in the
|
with a decay constant of \SI{2.6}{\MeV}. The partial emission rate in the
|
||||||
energy range from \SIrange{4}{8}{\MeV} is $(1.7 \pm 0.1)\%$, and the total
|
energy range from \SIrange{4}{8}{\MeV} is $(1.7 \pm 0.1)\%$ per nuclear
|
||||||
|
muon capture, and the total
|
||||||
emission rate assuming the shape holds for the whole spectrum is
|
emission rate assuming the shape holds for the whole spectrum is
|
||||||
$(3.5\pm0.2)\%$.
|
$(3.5\pm0.2)\%$ per nuclear muon capture.
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
The emission rate is consistent with the lower limit of 2.8\% set by
|
The emission rate is consistent with the lower limit of 2.8\% set by
|
||||||
Wyttenbach et al.~\cite{WyttenbachBaertschi.etal.1978}. It is also compatible
|
Wyttenbach et al.~\cite{WyttenbachBaertschi.etal.1978}. It is also compatible
|
||||||
with the theoretical calculation by Lifshitz and
|
with the theoretical calculation by Lifshitz and
|
||||||
Singer~\cite{LifshitzSinger.1980}. Compared with the emission rate from
|
Singer~\cite{LifshitzSinger.1980}. Compared with the existing result on
|
||||||
silicon, our result is smaller.
|
silicon~\cite{SobottkaWills.1968}, the emission rate from aluminium is
|
||||||
|
significantly smaller and the spectrum is softer.
|
||||||
|
|
||||||
The proton rate and spectrum have been used to optimise the planned proton
|
The proton rate and spectrum have been used to optimise the planned proton
|
||||||
absorber for the drift chamber of the COMET Phase-I. The resulted proton hit
|
absorber for the drift chamber of the COMET Phase-I. The resulted proton hit
|
||||||
rate with the baseline configuration is very small compared with the current
|
rate with the baseline configuration is very small compared with the current
|
||||||
figure. It is safe to remove the proton absorber altogether. This would make
|
figure.The recommendation to the COMET Phase-I is to remove the proton
|
||||||
a strong impact to the drift chamber design. The AlCap experiment is going to
|
absorber altogether. The momentum resolution of the drift chamber will be
|
||||||
|
slightly improved, and the level of integrated charge will still remain below
|
||||||
|
the safe level for the chamber.
|
||||||
|
|
||||||
|
The AlCap experiment is going to
|
||||||
submit a beam time request for the 2015 run to collect more data and other
|
submit a beam time request for the 2015 run to collect more data and other
|
||||||
measurements for neutrons and gamma rays.
|
measurements for neutrons and gamma rays.
|
||||||
|
|||||||
@@ -57,11 +57,27 @@ detector hit rate of the COMET Phase-I.
|
|||||||
|
|
||||||
|
|
||||||
% Acknowledgements
|
% Acknowledgements
|
||||||
%\begin{acknowledgements}
|
\begin{acknowledgements}
|
||||||
%\thispagestyle{empty}
|
\thispagestyle{empty}
|
||||||
%Of the many people who deserve thanks, some are particularly prominent,
|
First and foremost I would like to thank my supervisor Yoshitaka
|
||||||
%such as my supervisor Professor Yoshitaka Kuno.
|
Kuno, for his great support and almost infinite patience in last four years.
|
||||||
%\end{acknowledgements}
|
I am also grateful to all members of the Kuno group, Department of
|
||||||
|
Physics, Osaka University. Thanks to Akira Sato, Hideyuki Sakamoto for the
|
||||||
|
knowledge and supervision they have provided. And to Takahisa Itahashi
|
||||||
|
for the advice and allowing me to practice on his expensive silicon detectors.
|
||||||
|
|
||||||
|
The measurement described in this thesis is the product of effort of all
|
||||||
|
members of the AlCap Collaboration. Special thanks to Peter Kammel for
|
||||||
|
always pushing the experiment forward and your very helpful advices.
|
||||||
|
I enjoyed the stays at your group at University of Washington in Seattle
|
||||||
|
a lot. I would also like to thank the
|
||||||
|
fellow graduate students in the collaboration Andy, John, Ben, Damien for
|
||||||
|
all the hard work in the beam time, in the analysis phase, and also for
|
||||||
|
the beers. I wish you all success with your work.
|
||||||
|
|
||||||
|
Finally, I would like to thank my family and friends. Without your love and
|
||||||
|
support I wouldn't make it through these long years of graduate school.
|
||||||
|
\end{acknowledgements}
|
||||||
|
|
||||||
|
|
||||||
%% Preface
|
%% Preface
|
||||||
|
|||||||
Binary file not shown.
Binary file not shown.
@@ -196,6 +196,26 @@ bookmarks
|
|||||||
\ignorespacesafterend%
|
\ignorespacesafterend%
|
||||||
}
|
}
|
||||||
|
|
||||||
|
\newenvironment{acknowledgements}{%
|
||||||
|
\cleardoublepage%
|
||||||
|
\adjustwidth{\@declarationextramargin}{\@declarationextramargin}%
|
||||||
|
\vspace*{\@frontmattertopskip}%
|
||||||
|
\begin{center}%
|
||||||
|
\begingroup
|
||||||
|
\ifx\@sftitles\@empty\else\sf\fi
|
||||||
|
{\LARGE\textbf{Acknowledgements}}%
|
||||||
|
\endgroup
|
||||||
|
\end{center}%
|
||||||
|
\vspace*{1cm}%
|
||||||
|
}{%
|
||||||
|
%\newline \newline \newline%
|
||||||
|
%\begin{flushright}
|
||||||
|
% \thesisauthor\newline
|
||||||
|
% \today\newline
|
||||||
|
%\end{flushright}
|
||||||
|
\endadjustwidth%
|
||||||
|
\ignorespacesafterend%
|
||||||
|
}
|
||||||
%% Change the spacing of lines
|
%% Change the spacing of lines
|
||||||
\DeclareRobustCommand{\setspacing}[1]{%
|
\DeclareRobustCommand{\setspacing}[1]{%
|
||||||
\setfrontmatterspacing{#1}%
|
\setfrontmatterspacing{#1}%
|
||||||
|
|||||||
@@ -128,6 +128,25 @@
|
|||||||
Timestamp = {2014-10-11}
|
Timestamp = {2014-10-11}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{AhmadAzuelos.etal.1988a,
|
||||||
|
Title = {Search for muon-electron and muon-positron conversion},
|
||||||
|
Author = {Ahmad, S. and Azuelos, G. and Blecher, M. and Bryman, D. and Burnham, R. and Clifford, E. and Depommier, P. and Dixit, M. and Gotow, K. and Hargrove, C. and Hasinoff, M. and Leitch, M. and Macdonald, J. and Mes, H. and Navon, I. and Numao, T. and Poutissou, J-M. and Poutissou, R. and Schlatter, P. and Spuller, J. and Summhammer, J.},
|
||||||
|
Journal = {Phys. Rev. D},
|
||||||
|
Year = {1988},
|
||||||
|
|
||||||
|
Month = {Oct},
|
||||||
|
Pages = {2102--2120},
|
||||||
|
Volume = {38},
|
||||||
|
|
||||||
|
Doi = {10.1103/PhysRevD.38.2102},
|
||||||
|
Issue = {7},
|
||||||
|
Numpages = {19},
|
||||||
|
Owner = {NT},
|
||||||
|
Publisher = {American Physical Society},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://link.aps.org/doi/10.1103/PhysRevD.38.2102}
|
||||||
|
}
|
||||||
|
|
||||||
@Article{AhmadAzuelos.etal.1988,
|
@Article{AhmadAzuelos.etal.1988,
|
||||||
Title = {Search for muon-electron and muon-positron conversion},
|
Title = {Search for muon-electron and muon-positron conversion},
|
||||||
Author = {Ahmad, S and Azuelos, G and Blecher, M and Bryman, DA and Burnham, RA and Clifford, ETH and Depommier, P and Dixit, MS and Gotow, K and Hargrove, CK and others},
|
Author = {Ahmad, S and Azuelos, G and Blecher, M and Bryman, DA and Burnham, RA and Clifford, ETH and Depommier, P and Dixit, MS and Gotow, K and Hargrove, CK and others},
|
||||||
@@ -357,6 +376,42 @@
|
|||||||
Timestamp = {2014-04-24}
|
Timestamp = {2014-04-24}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{BadertscherBorer.etal.1982a,
|
||||||
|
Title = {A search for muon-electron and muon-positron conversion in sulfur },
|
||||||
|
Author = {A. Badertscher and K. Borer and G. Czapek and B. Hahn and E. Hugentobler and A. Markees and T. Marti and U. Moser and E. Ramseyer and J. Schacher and H. Scheidiger and P. Schlatter and G. Viertel and W. Zeller},
|
||||||
|
Journal = {Nuclear Physics A },
|
||||||
|
Year = {1982},
|
||||||
|
Number = {2<EFBFBD>3},
|
||||||
|
Pages = {406 - 440},
|
||||||
|
Volume = {377},
|
||||||
|
|
||||||
|
Doi = {http://dx.doi.org/10.1016/0375-9474(82)90049-5},
|
||||||
|
ISSN = {0375-9474},
|
||||||
|
Keywords = {Nuclear reactions },
|
||||||
|
Owner = {NT},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://www.sciencedirect.com/science/article/pii/0375947482900495}
|
||||||
|
}
|
||||||
|
|
||||||
|
@Article{BadertscherBorer.etal.1977,
|
||||||
|
Title = {Upper Limit for Muon-Electron Conversion in Sulfur},
|
||||||
|
Author = {Badertscher, A. and Borer, K. and Czapek, H. and Hahn, B. and Hugentobler, E. and Markees, A. and Moser, U. and Redwine, R. and Schacher, J. and Scheidiger, H. and Schlatter, P. and Viertel, G.},
|
||||||
|
Journal = {Phys. Rev. Lett.},
|
||||||
|
Year = {1977},
|
||||||
|
|
||||||
|
Month = {Nov},
|
||||||
|
Pages = {1385--1387},
|
||||||
|
Volume = {39},
|
||||||
|
|
||||||
|
Doi = {10.1103/PhysRevLett.39.1385},
|
||||||
|
Issue = {22},
|
||||||
|
Numpages = {3},
|
||||||
|
Owner = {NT},
|
||||||
|
Publisher = {American Physical Society},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://link.aps.org/doi/10.1103/PhysRevLett.39.1385}
|
||||||
|
}
|
||||||
|
|
||||||
@Article{BalandinGrebenyuk.etal.1978,
|
@Article{BalandinGrebenyuk.etal.1978,
|
||||||
Title = {{Energy Spectra and Asymmetry of Charged Particles from
|
Title = {{Energy Spectra and Asymmetry of Charged Particles from
|
||||||
Negative Muon Capture by Nuclei}},
|
Negative Muon Capture by Nuclei}},
|
||||||
@@ -386,6 +441,22 @@
|
|||||||
Timestamp = {2014.02.10}
|
Timestamp = {2014.02.10}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{BartleyDavies.etal.1964,
|
||||||
|
Title = {A search for neutrinoless decay modes of the negative muon },
|
||||||
|
Author = {J.H. Bartley and H. Davies and H. Muirhead and T. Woodhead},
|
||||||
|
Journal = {Physics Letters },
|
||||||
|
Year = {1964},
|
||||||
|
Number = {3},
|
||||||
|
Pages = {258 - 259},
|
||||||
|
Volume = {13},
|
||||||
|
|
||||||
|
Doi = {http://dx.doi.org/10.1016/0031-9163(64)90479-2},
|
||||||
|
ISSN = {0031-9163},
|
||||||
|
Owner = {NT},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://www.sciencedirect.com/science/article/pii/0031916364904792}
|
||||||
|
}
|
||||||
|
|
||||||
@Article{BauerBortels.1990,
|
@Article{BauerBortels.1990,
|
||||||
Title = {Response of Si detectors to electrons, deuterons and alpha particles},
|
Title = {Response of Si detectors to electrons, deuterons and alpha particles},
|
||||||
Author = {Bauer, P and Bortels, G},
|
Author = {Bauer, P and Bortels, G},
|
||||||
@@ -586,6 +657,45 @@
|
|||||||
Timestamp = {2014-04-09}
|
Timestamp = {2014-04-09}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{Bryman1985,
|
||||||
|
Title = {Search for \textit{$\mu${}} - \textit{e} conversion in Ti},
|
||||||
|
Author = {Bryman, D. A. and Clifford, E. T. H. and Leitch, M. J. and Navon, I. and Numao, T. and Schlatter, P. and Dixit, M. S. and Hargrove, C. K. and Mes, H. and Burnham, R. A. and Hasinoff, M. and Poutissou, J.-M. and Macdonald, J. A. and Spuller, J. and Azuelos, G. and Depommier, P. and Martin, J.-P. and Poutissou, R. and Blecher, M. and Gotow, K. and Carter, A. L. and Anderson, H. L. and Wright, S. C.},
|
||||||
|
Journal = {Phys. Rev. Lett.},
|
||||||
|
Year = {1985},
|
||||||
|
|
||||||
|
Month = {Jul},
|
||||||
|
Pages = {465--468},
|
||||||
|
Volume = {55},
|
||||||
|
|
||||||
|
__markedentry = {[nam:6]},
|
||||||
|
Doi = {10.1103/PhysRevLett.55.465},
|
||||||
|
Issue = {5},
|
||||||
|
Numpages = {0},
|
||||||
|
Owner = {nam},
|
||||||
|
Publisher = {American Physical Society},
|
||||||
|
Timestamp = {2015.04.27},
|
||||||
|
Url = {http://link.aps.org/doi/10.1103/PhysRevLett.55.465}
|
||||||
|
}
|
||||||
|
|
||||||
|
@Article{BrymanBlecher.etal.1972,
|
||||||
|
Title = {Search for the Reaction },
|
||||||
|
Author = {Bryman, D. and Blecher, M. and Gotow, K. and Powers, R.},
|
||||||
|
Journal = {Phys. Rev. Lett.},
|
||||||
|
Year = {1972},
|
||||||
|
|
||||||
|
Month = {May},
|
||||||
|
Pages = {1469--1471},
|
||||||
|
Volume = {28},
|
||||||
|
|
||||||
|
Doi = {10.1103/PhysRevLett.28.1469},
|
||||||
|
Issue = {22},
|
||||||
|
Numpages = {3},
|
||||||
|
Owner = {NT},
|
||||||
|
Publisher = {American Physical Society},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://link.aps.org/doi/10.1103/PhysRevLett.28.1469}
|
||||||
|
}
|
||||||
|
|
||||||
@TechReport{COMET.2007,
|
@TechReport{COMET.2007,
|
||||||
Title = {An Experimental Search for Lepton Flavor Violating $\mu^--e^-$ Conversion at Sensitivity of $10^{-16}$ with a Slow-Extracted Bunched Proton Beam},
|
Title = {An Experimental Search for Lepton Flavor Violating $\mu^--e^-$ Conversion at Sensitivity of $10^{-16}$ with a Slow-Extracted Bunched Proton Beam},
|
||||||
Author = {D. Bryman and R. Palmer and Y. Iwashita and M.
|
Author = {D. Bryman and R. Palmer and Y. Iwashita and M.
|
||||||
@@ -901,6 +1011,22 @@
|
|||||||
Url = {http://indico.cern.ch/event/107747/session/1/contribution/71/material/paper/0.pdf}
|
Url = {http://indico.cern.ch/event/107747/session/1/contribution/71/material/paper/0.pdf}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{DohmenGroth.etal.1993,
|
||||||
|
Title = {Test of lepton-flavour conservation in mu-e conversion on titanium },
|
||||||
|
Author = {C. Dohmen and K.-D. Groth and B. Heer and W. Honecker and G. Otter and B. Steinr<6E>cken and P. Wintz and V. Djordjadze and J. Hofmann and T. Kozlowski and S. Playfer and W. Bertl and J. Egger and W. Herold and B. Krause and H.K. Walter and R. Engfer and Ch. Findeisen and M. Grossmann-Handschin and E.A. Hermes and F. Muheim and C.B. Niebuhr and H.S. Pruys and L. Ricken and D. Vermeulen and A. van der Schaaf},
|
||||||
|
Journal = {Physics Letters B },
|
||||||
|
Year = {1993},
|
||||||
|
Number = {4},
|
||||||
|
Pages = {631 - 636},
|
||||||
|
Volume = {317},
|
||||||
|
|
||||||
|
Doi = {http://dx.doi.org/10.1016/0370-2693(93)91383-X},
|
||||||
|
ISSN = {0370-2693},
|
||||||
|
Owner = {NT},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://www.sciencedirect.com/science/article/pii/037026939391383X}
|
||||||
|
}
|
||||||
|
|
||||||
@Article{EcksteinPratt.1959,
|
@Article{EcksteinPratt.1959,
|
||||||
Title = {Radiative muon decay },
|
Title = {Radiative muon decay },
|
||||||
Author = {S.G Eckstein and R.H Pratt},
|
Author = {S.G Eckstein and R.H Pratt},
|
||||||
@@ -1279,6 +1405,26 @@
|
|||||||
Timestamp = {2014-04-09}
|
Timestamp = {2014-04-09}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{HoneckerDohmen.etal.1996,
|
||||||
|
Title = {Improved Limit on the Branching Ratio of $$\mu${}$\rightarrow${}\mathit{e}$ Conversion on Lead},
|
||||||
|
Author = {Honecker, W. and Dohmen, C. and Haan, H. and Junker, D. and Otter, G. and Starlinger, M. and Wintz, P. and Hofmann, J. and Bertl, W. and Egger, J. and Krause, B. and Eggli, S. and Engfer, R. and Findeisen, Ch. and Hermes, E. and Kozlowski, T. and Niebuhr, C. and Pruys, H. and van der Schaaf, A.},
|
||||||
|
Journal = {Phys. Rev. Lett.},
|
||||||
|
Year = {1996},
|
||||||
|
|
||||||
|
Month = {Jan},
|
||||||
|
Pages = {200--203},
|
||||||
|
Volume = {76},
|
||||||
|
|
||||||
|
Collaboration = {(SINDRUM II Collaboration)},
|
||||||
|
Doi = {10.1103/PhysRevLett.76.200},
|
||||||
|
Issue = {2},
|
||||||
|
Numpages = {4},
|
||||||
|
Owner = {NT},
|
||||||
|
Publisher = {American Physical Society},
|
||||||
|
Timestamp = {2014-12-10},
|
||||||
|
Url = {http://link.aps.org/doi/10.1103/PhysRevLett.76.200}
|
||||||
|
}
|
||||||
|
|
||||||
@Article{Huff.1961,
|
@Article{Huff.1961,
|
||||||
Title = {Decay rate of bound muons },
|
Title = {Decay rate of bound muons },
|
||||||
Author = {Robert W Huff},
|
Author = {Robert W Huff},
|
||||||
@@ -1343,7 +1489,6 @@
|
|||||||
Pages = {385},
|
Pages = {385},
|
||||||
Volume = {A392},
|
Volume = {A392},
|
||||||
|
|
||||||
__markedentry = {[NT:]},
|
|
||||||
Doi = {10.1016/0375-9474(83)90134-3},
|
Doi = {10.1016/0375-9474(83)90134-3},
|
||||||
File = {Published version:IsaakEngfer.etal.1983.pdf:PDF},
|
File = {Published version:IsaakEngfer.etal.1983.pdf:PDF},
|
||||||
Owner = {NT},
|
Owner = {NT},
|
||||||
@@ -1588,7 +1733,6 @@
|
|||||||
Pages = {368-380},
|
Pages = {368-380},
|
||||||
Volume = {A305},
|
Volume = {A305},
|
||||||
|
|
||||||
__markedentry = {[NT:]},
|
|
||||||
Doi = {10.1016/0375-9474(78)90345-7},
|
Doi = {10.1016/0375-9474(78)90345-7},
|
||||||
File = {Published version:KozlowskiZglinski.1978.pdf:PDF},
|
File = {Published version:KozlowskiZglinski.1978.pdf:PDF},
|
||||||
Owner = {NT},
|
Owner = {NT},
|
||||||
@@ -1604,7 +1748,6 @@
|
|||||||
Pages = {222-224},
|
Pages = {222-224},
|
||||||
Volume = {B50},
|
Volume = {B50},
|
||||||
|
|
||||||
__markedentry = {[NT:]},
|
|
||||||
Doi = {10.1016/0370-2693(74)90543-7},
|
Doi = {10.1016/0370-2693(74)90543-7},
|
||||||
File = {Published version:KozlowskiZglinski.1974.pdf:PDF},
|
File = {Published version:KozlowskiZglinski.1974.pdf:PDF},
|
||||||
Owner = {NT},
|
Owner = {NT},
|
||||||
@@ -1620,8 +1763,6 @@
|
|||||||
Year = {1974},
|
Year = {1974},
|
||||||
Pages = {721-725},
|
Pages = {721-725},
|
||||||
Volume = {19},
|
Volume = {19},
|
||||||
|
|
||||||
__markedentry = {[NT:6]},
|
|
||||||
Owner = {NT},
|
Owner = {NT},
|
||||||
Slaccitation = {%%CITATION = NUKLA,19,721;%%},
|
Slaccitation = {%%CITATION = NUKLA,19,721;%%},
|
||||||
Timestamp = {2014-10-16}
|
Timestamp = {2014-10-16}
|
||||||
@@ -1920,6 +2061,25 @@
|
|||||||
Url = {http://www.sciencedirect.com/science/article/pii/S0168900207008790}
|
Url = {http://www.sciencedirect.com/science/article/pii/S0168900207008790}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@Article{Mankel.2004,
|
||||||
|
Title = {{Pattern recognition and event reconstruction in particle
|
||||||
|
physics experiments}},
|
||||||
|
Author = {Mankel, Rainer},
|
||||||
|
Journal = {Rept.Prog.Phys.},
|
||||||
|
Year = {2004},
|
||||||
|
Pages = {553},
|
||||||
|
Volume = {67},
|
||||||
|
Archiveprefix = {arXiv},
|
||||||
|
Doi = {10.1088/0034-4885/67/4/R03},
|
||||||
|
Eprint = {physics/0402039},
|
||||||
|
File = {Published version:Mankel.2004.pdf:PDF},
|
||||||
|
Owner = {NT},
|
||||||
|
Primaryclass = {physics},
|
||||||
|
Reportnumber = {DESY-04-008},
|
||||||
|
Slaccitation = {%%CITATION = PHYSICS/0402039;%%},
|
||||||
|
Timestamp = {2015-01-07}
|
||||||
|
}
|
||||||
|
|
||||||
@Article{MarcianoSanda.1977,
|
@Article{MarcianoSanda.1977,
|
||||||
Title = {{Exotic Decays of the Muon and Heavy Leptons in Gauge
|
Title = {{Exotic Decays of the Muon and Heavy Leptons in Gauge
|
||||||
Theories}},
|
Theories}},
|
||||||
|
|||||||
Reference in New Issue
Block a user