| 1 | \subsection{Proton decay sensitivity}
|
|---|
| 2 | For proton decay, no specific simulation for MEMPHYS has been carried out yet.
|
|---|
| 3 | We therefore rely on the study done by UNO, adapting the results to MEMPHYS
|
|---|
| 4 | (which has an overall better coverage) when possible.
|
|---|
| 5 | \subsubsection{$p \rightarrow e^+\pi^0$}
|
|---|
| 6 |
|
|---|
| 7 | Following UNO study,
|
|---|
| 8 | the detection efficiency of $p \rightarrow e^+\pi^0$
|
|---|
| 9 | (3 showering rings event) is $\epsilon=$43\%
|
|---|
| 10 | for a 20 inch-PMT coverage of 40\% or its equivalent, as envisioned for
|
|---|
| 11 | MEMPHYS. The corresponding estimated
|
|---|
| 12 | atmospheric neutrino induced background is at the level of 2.25 events/Mt.yr.
|
|---|
| 13 | From these efficiencies and background levels,
|
|---|
| 14 | proton decay sensitivity as a function of detector exposure can be
|
|---|
| 15 | estimated (see Fig. \ref{pdk1}).
|
|---|
| 16 |
|
|---|
| 17 | \begin{figure}[htb]
|
|---|
| 18 | \begin{minipage}[c]{0.44\textwidth}
|
|---|
| 19 | \epsfig{figure=./figures/epi0-WC-Shiozawa.eps,width=\textwidth,angle=0}
|
|---|
| 20 | \caption{\it \label{pdk1} Sensitivity for $e^+\pi^0$ proton decay
|
|---|
| 21 | lifetime, as determined by UNO \cite{uno}. MEMPHYS corresponds to case (A).}
|
|---|
| 22 | \end{minipage}
|
|---|
| 23 | \begin{minipage}[c]{0.05\textwidth}
|
|---|
| 24 | ~
|
|---|
| 25 | \end{minipage}
|
|---|
| 26 | \begin{minipage}[c]{0.44\textwidth}
|
|---|
| 27 | \epsfig{figure=./figures/Knu-WC-Shiozawa.eps,width=\textwidth,angle=0}
|
|---|
| 28 | \caption{\it \label{pdk9_jbz}
|
|---|
| 29 | Expected sensitivity on $\nu K^+$ proton decay as a function of MEMPHYS
|
|---|
| 30 | exposure \cite{uno} (see text for details).}
|
|---|
| 31 | \end{minipage}
|
|---|
| 32 | \end{figure}
|
|---|
| 33 |
|
|---|
| 34 | $10^{35}$ years partial
|
|---|
| 35 | lifetime could be reached at the 90\% CL for a 5 Mt.yr exposure with MEMPHYS
|
|---|
| 36 | (similar to case A in figure~\ref{pdk1}).
|
|---|
| 37 |
|
|---|
| 38 |
|
|---|
| 39 | \subsubsection{$p \rightarrow \overline{\nu}K^+$}
|
|---|
| 40 |
|
|---|
| 41 | Since the $K^+$ is below the \v{C}erenkov threshold, this channel is
|
|---|
| 42 | detected via the decay products of the kaon: a 256 MeV/c muon and
|
|---|
| 43 | its decay electron (type I) or a 205 MeV/c $\pi^+$ and $\pi^0$
|
|---|
| 44 | (type II), with the possibility of a delayed (12 ns) coincidence
|
|---|
| 45 | with the 6 MeV nuclear de-excitation prompt $\gamma$ (Type III).
|
|---|
| 46 | In Super-Kamiokande, the efficiency for the reconstruction of
|
|---|
| 47 | $p \rightarrow \overline{\nu}K^+$ is $\epsilon=$ 33\% (I), 6.8\% (II)
|
|---|
| 48 | and 8.8\% (III),
|
|---|
| 49 | and the background is at the 2100, 22 and 6/Mt.yr level. For the
|
|---|
| 50 | prompt $\gamma$ method, the background is dominated by
|
|---|
| 51 | mis-reconstruction. As stated by UNO, there are good
|
|---|
| 52 | reasons to believe that this
|
|---|
| 53 | background can be lowered at the level of 1/Mt.yr corresponding
|
|---|
| 54 | to the atmospheric neutrino interaction $\nu p \rightarrow \nu
|
|---|
| 55 | \Lambda K^+$. In these conditions, and using Super-Kamiokande performances,
|
|---|
| 56 | a 5 Mt.yr MEMPHYS exposure would
|
|---|
| 57 | allow to reach the $2\times10^{34}$ years partial lifetime
|
|---|
| 58 | (see Fig. \ref{pdk9_jbz}).
|
|---|
| 59 |
|
|---|
| 60 | %\subsubsection{Comparison with liquid argon detectors}
|
|---|
| 61 | %Comparisons have been done between megaton scale \v{C}erenkov detectors
|
|---|
| 62 | %and liquid argon TPC's with a mass of 100 kilotons. The main results show an
|
|---|
| 63 | %advantage to \v{C}erenkov detectors for the $e^+ \pi^0$ channel, due to their
|
|---|
| 64 | %higher mass, while liquid argon TPC's get better results for the
|
|---|
| 65 | %$\bar\nu K^+$ channel, due to a much better detection efficiency.
|
|---|
| 66 | %The two techniques look therefore quite complementary.
|
|---|
| 67 |
|
|---|
