\documentclass[presentation]{beamer} %\documentclass[presentation,aspectratio=169]{beamer} % Replacing 'presentation' with 'handout' in the above line % will produce 4 slides per page. % The hyperref option makes it possible to include hyperlinks. \mode { \usetheme{Boadilla} \setbeamercovered{transparent} } \usepackage[english]{babel} \usepackage[latin1]{inputenc} \usepackage{times} \usepackage[T1]{fontenc} %\usepackage{wrapfig} \usepackage{amsmath} \mode{ \usepackage{pgfpages} \pgfpagesuselayout{4 on 1}[letterpaper,landscape,border shrink=5mm] \setbeamercolor{background canvas}{bg=black!10} } \setbeamertemplate{footline} { \leavevmode% \hbox{% \begin{beamercolorbox}[wd=.333333\paperwidth,ht=2.25ex,dp=1ex,center]{author in head/foot}% \usebeamerfont{author in head/ foot}\insertshortauthor%&\approx& (\insertshorti \end{beamercolorbox}% \begin{beamercolorbox}[wd=.333333\paperwidth,ht=2.25ex,dp=1ex,center]{title in head/foot}% \usebeamerfont{title in head/foot}\insertshorttitle \end{beamercolorbox}% \begin{beamercolorbox}[wd=.333333\paperwidth,ht=2.25ex,dp=1ex,right]{date in head/foot}% \usebeamerfont{date in head/foot}\insertshortdate\hspace*{2em} \insertframenumber / \inserttotalframenumber\hspace*{2ex} \end{beamercolorbox}}% \vskip0pt% } %gets rid of bottom navigation bars %\setbeamertemplate{footline}[frame number]{} %gets rid of bottom navigation symbols %\setbeamertemplate{navigation symbols}{} %gets rid of footer %will override 'frame number' instruction above %comment out to revert to previous/default definitions %\setbeamertemplate{footline}{} \newcommand{\backupbegin}{ \newcounter{framenumberappendix} \setcounter{framenumberappendix}{\value{framenumber}} } \newcommand{\backupend}{ \addtocounter{framenumberappendix}{-\value{framenumber}} \addtocounter{framenumber}{\value{framenumberappendix}} } %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %\title[GEANT4/EGS5]{GEANT4/EGS5} \title[SENSEI]{The SENSEI Experiment: Status and Plans} \author[Sho Uemura]{Sho Uemura\\Tel Aviv University\\SENSEI Collaboration} %\institute{bumming around} \date[March 28, 2020] %\titlegraphic{ %\includegraphics[height=0.1\textheight]{SLAC_Logo}\hspace*{4.75cm}~ %\includegraphics[height=0.1\textheight]{partner_logo_v2} %} \begin{document} %\setcounter{framenumber}{2} \begin{frame} \titlepage \end{frame} \begin{frame} \begin{itemize} \item Skipper overview \begin{itemize} \item Fano factor measurement as example \end{itemize} \item New CCDs \begin{itemize} \item Packaging tall and wide CCDs \end{itemize} \item MINOS apparatus, description of dataset \item Backgrounds \begin{itemize} \item Uniform backgrounds: DC, SC \item CTI \item Halo \begin{itemize} \item Not CTI: exists in all directions \item Not Poisson: ratio of 1- and 2-pixel 2e- events \end{itemize} \end{itemize} \item Signal, charge diffusion (or should this be later?) \item 1e- measurement \begin{itemize} \item Measurement of exposure-independent component \end{itemize} \item 2e- measurement \begin{itemize} \item Measurement of exposure-independent component \item If we have a 2 e- excess over Poisson: present evidence for halo 2e- events \end{itemize} \item Plans \begin{itemize} \item SNOLAB ``phase-1'' system: work in progress \item R\&D on packaging, DC, SC \item 100-gram experiment with low-bkgd shield \begin{itemize} \item or is it 50 grams? \end{itemize} \end{itemize} \end{itemize} \end{frame} %E772/E866 interpretation: %https://arxiv.org/pdf/hep-ph/0105195.pdf %E906 preliminary interpretation (Arleo): %https://arxiv.org/pdf/1810.05120.pdf %E906 projections (Vitev): %https://arxiv.org/pdf/1010.3708.pdf %NIM paper: %https://arxiv.org/pdf/1706.09990.pdf %motivation: benchmark for QGP hot nuclear matter %Drell-Yan %compare to SIDIS: initial vs. final state, hadronization %shadowing vs. energy loss %kinematic ranges %apparatus %schedule %other measurements, E1039 %backgrounds %\begin{frame}{Jet quenching and cold nuclear matter} % \begin{columns} % \column{0.65\textwidth} % \begin{itemize} % \item Jet quenching in heavy-ion collisions is a key probe of the QGP % \item $R_{AA}$ shows clear suppression in $A+A$ relative to $p+p$, attributed to parton energy loss in final-state interaction % \item But cold nuclear matter effects also contribute: % \begin{itemize} % \item Nuclear modification of PDFs % \item Parton energy loss in initial-state interaction % \end{itemize} % %\item Cold nuclear matter is studied in $p+A$, $d+A$ at RHIC/LHC, and modification is seen % \item $p+A$, $d+A$ at RHIC/LHC are used to benchmark CNM effects % \begin{itemize} % \item We see modification relative to $p+p$: what is the cause? % \end{itemize} % %\item Fixed-target experiments (SIDIS, Drell-Yan) have unique power in isolating effects % %\item $p+A$ collisions also show modification relative to $p+p$: cold nuclear matter effect % %\begin{itemize} % %\item What is it? % %\end{itemize} % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{emcal_location} % %\end{center} % \column{0.3\textwidth} % \includegraphics[width=\textwidth]{dau_150904657} % % \tiny{Adare et al, Phys. Rev. Lett. 116, 122301 (2016)} % \end{columns} %\end{frame} % %\begin{frame}{Initial-state energy loss} % \begin{columns} % \column{0.65\textwidth} % \begin{itemize} % \item Models suggest significant radiative energy loss in CNM, initial-state energy loss in particular % \item Energy loss is certainly not the whole story in cold nuclear matter, but we must understand it % \begin{itemize} % \item CNM energy loss is a crucial benchmark for QGP measurements % \item Fixed-target experiments (SIDIS, Drell-Yan) have unique power in isolating effects % \end{itemize} % %\item Initial-state and final-state energy loss have different Vitev, Phys.Rev. C75, 064906 (2007) % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{emcal_location} % %\end{center} % \column{0.35\textwidth} % \includegraphics[width=\textwidth]{cnm_eloss} % % \tiny{Vitev, Phys.Rev. C75, 064906 (2007)} % \end{columns} %\end{frame} % %%\begin{frame}{Energy loss in fixed-target experiments} %%\begin{columns} %%\column{0.65\textwidth} %%\begin{itemize} %%\item Fixed target SIDIS and Drell-Yan experiments are sensitive to energy loss %%\item SIDIS ($e+A$): final-state energy loss followed by hadronization %%\item Drell-Yan ($p+A$): clean channel for initial-state energy loss %%\end{itemize} %%%\begin{center} %%%\includegraphics[width=\textwidth]{emcal_location} %%%\end{center} %%\column{0.35\textwidth} %%%\includegraphics[width=\textwidth]{phenix_emcal} %%\end{columns} %%\end{frame} %% %%\begin{frame}{Energy loss measurement in SIDIS} %%\begin{columns} %%\column{0.65\textwidth} %%\begin{itemize} %%\item Fixed target SIDIS and Drell-Yan experiments are sensitive to energy loss %%\item SIDIS ($e+A$): final-state energy loss %%\item Drell-Yan ($p+A$): initial-state energy loss %%\end{itemize} %%%\begin{center} %%%\includegraphics[width=\textwidth]{emcal_location} %%%\end{center} %%\column{0.35\textwidth} %%%\includegraphics[width=\textwidth]{phenix_emcal} %%\end{columns} %%\end{frame} % %\begin{frame}{Energy loss measurement with Drell-Yan} % \begin{columns} % \column{0.65\textwidth} % \begin{itemize} % \item Quark (antiquark) in beam proton annhilates with antiquark (quark) in target nucleus % \begin{itemize} % \item Fixed-target spectrometer (large $x_{beam}$) selects beam valence quark and target sea antiquark % \end{itemize} % \item Beam quark is subject to initial-state energy loss; dimuon final state interacts minimally with medium (EM interaction, much weaker than strong interaction) % \item Different models of initial-state energy loss predict different nuclear dependence: % \begin{itemize} % \item Gavin and Milana: $\Delta x_{beam} = -\kappa_1x_{beam}A^{1/3}$ % \item Brodsky and Hoyer: $\Delta x_{beam} = -\frac{\kappa_2}{s}A^{1/3}$ % \item Baier et al: $\Delta x_{beam} = -\frac{\kappa_3}{s}A^{2/3}$ % \end{itemize} % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{emcal_location} % %\end{center} % \column{0.35\textwidth} % \includegraphics[width=\textwidth]{targetbeam} % % \includegraphics[width=\textwidth]{dy_energyloss} % \end{columns} %\end{frame} % %\begin{frame}{Energy loss measurement with Drell-Yan} % \begin{columns} % \column{0.65\textwidth} % \begin{itemize} % \item Measure DY rate with different nuclear targets: D or C target with negligible energy loss (and minimal isospin effects), and a range of heavier targets % \item The beam parton loses energy, shifting $x_{beam}$: measurable as nuclear modification $R_{pA}=\frac{\sigma^{pA}}{A\sigma^{pD}}$ % \begin{itemize} % \item Expect steeply falling $R_{pA}$ at large $x_{beam}$ or $x_F$ % \end{itemize} % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{emcal_location} % %\end{center} % \column{0.35\textwidth} % \includegraphics[width=\textwidth]{rpa} % \end{columns} %\end{frame} % %\begin{frame}{Previous DY measurement: E772/E866} % \begin{columns} % \column{0.65\textwidth} % \begin{itemize} % \item Measured $R_{pA}(x_F)$ using Be, Fe, W targets and the 800 GeV Tevatron proton beam, and observed significant nuclear modification % \item Drell-Yan acceptance covered $x_{beam} \in [0.21, 0.95]$, $x_{target} \in [0.01, 0.12]$ % \begin{itemize} % \item Small $x_{target}$ $\to$ substantial shadowing in the target nuclear PDF % \end{itemize} % \item Interpretations of the result differ: % \begin{itemize} % \item All shadowing, no measurable energy loss: Vasiliev et al., PRL 83 (1999) % \item Different shadowing model shows significant energy loss: Johnson et al., PRC 65 025203 (2002) % \end{itemize} % \item A lower beam energy would access larger $x_{target}$ and avoid shadowing % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{shadowing.png} % %\end{center} % \column{0.35\textwidth} % \includegraphics[width=\textwidth]{e866_ambiguity_10103708} % % \tiny{Neufeld et al., Phys. Lett. B 704 (2011) 590} % \end{columns} %\end{frame} % %\begin{frame}{The E906/SeaQuest experiment} % \begin{columns} % \column{0.4\textwidth} % \begin{itemize} % \item Fixed-target muon spectrometer, 120 GeV Main Injector proton beam % %\item Primary program: Drell-Yan measurements of sea quark distributions % %\begin{itemize} % %\item E906 (unpolarized targets, 2012--2017), E1039 (polarized targets, 2019--2020) % %\end{itemize} % %\item Measurement of the nucleon sea quark distribution using Drell-Yan% ($q\bar{q}\to \mu^+\mu^-$) % \item Thin ($\sim$10\%$\lambda_I$) rotating targets: LH2, LD2, C, Fe, W % \item Iron-filled dipole magnet focuses muons and absorbs everything else % \item Drift chambers for tracking, scintillator hodoscopes for trigger % \end{itemize} % %\begin{center} % %\end{center} % \column{0.6\textwidth} % \begin{flushright} % \includegraphics[width=\textwidth]{seaquest_setup} % \tiny{arXiv:1706.09990} % \end{flushright} % \end{columns} %\end{frame} % % %%\begin{frame}{Other SeaQuest programs} % %\begin{columns} % %\column{0.7\textwidth} % %\begin{itemize} % %\item Flavor asymmetry of sea quarks: extend E866/NuSea measurement to larger $x$ (other E906 focus) % %\item Sea quark Sivers function, using polarized target (E1039, coming soon!) % %\item Dark photon search: parasitic search for BSM physics (started during E906 and will continue) % %%\begin{itemize} % %%\item E906 (unpolarized targets, 2012--2017), E1039 (polarized targets, 2019--2020) % %%\end{itemize} % %%\item Measurement of the nucleon sea quark distribution using Drell-Yan% ($q\bar{q}\to \mu^+\mu^-$) % %%\item Thin ($\sim$10\%$\lambda_I$) rotating targets: LH2, LD2, C, Fe, W % %%\item Iron-filled dipole magnet serves as beam dump; second dipole magnet is used for momentum measurement % %%\item Drift chambers for tracking, scintillator hodoscopes for trigger % %\end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{emcal_location} % %\end{center} % %\column{0.3\textwidth} % %\begin{flushright} % %\includegraphics[width=\textwidth]{dbarubar} %% %% % %\includegraphics[width=\textwidth]{e1039_ssa} % %\end{flushright} % %\end{columns} %%\end{frame} % %%other programs: flavor asymmetry %\begin{frame}{Expectations for E906} % \begin{columns} % \column{0.55\textwidth} % \begin{itemize} % \item Drell-Yan acceptance covers $x_{beam} \in [0.4, 0.9]$, $x_{target} \in [0.1, 0.4]$ % \item Avoids the shadowing region of the nuclear PDFs: any nuclear dependence is due to energy loss % \item $x_{beam}$ range of 50--100 GeV is relevant to parton energies at RHIC and LHC % \end{itemize} % \column{0.45\textwidth} % \includegraphics[width=\textwidth]{e906_prediction_10103708} % % \tiny{Neufeld et al., Phys. Lett. B 704 (2011) 590} % \end{columns} % \begin{center} % \includegraphics[width=0.8\textwidth]{shadowing.png} % \end{center} %\end{frame} % %\begin{frame}{E906 timeline} % \begin{itemize} % \item First beam in 2012, first production-quality data in 2014 % \item Steady detector and beamline improvements % \item Data taking ended July 2017 % \begin{itemize} % \item Transitioning to E1039, with the same spectrometer but new polarized target % \end{itemize} % \end{itemize} % \begin{center} % \includegraphics[width=\textwidth]{e906_timeline} % \end{center} %\end{frame} % %\begin{frame}{Analysis} % \begin{columns} % \column{0.6\textwidth} % \begin{itemize} % \item Our observable is the Drell-Yan cross-section $\sigma^{pA}_{DY}(x_F)$ for each target % \begin{itemize} % %\item Bin the data in $x_F$ and use mass fits to extract charmonia, coincidence background, Drell-Yan % \item Reject beam dump background using track and vertex cuts % \item Use mass cuts and fits to isolate Drell-Yan rate from charmonia and coincidence background % \item Correct for detector and reconstruction efficiencies % \end{itemize} % %\item Challenges: % %\begin{itemize} % %\item Rate dependence % %\item Efficiency % %\item Coincidence background % %\end{itemize} % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{shadowing.png} % %\end{center} % \column{0.4\textwidth} % %\includegraphics[width=\textwidth]{dimuon_z} % % \includegraphics[width=\textwidth]{dimuon_mass} % \end{columns} %\end{frame} % %\begin{frame}{Coincidence background} % %\begin{columns} % %\column{0.65\textwidth} % \begin{itemize} % \item Random coincidences share the Drell-Yan kinematic range % \item Simulate coincidences using event mixing: take $\mu^-$ and $\mu^+$ from different events (``mixed data'') % \item What is the correct normalization of the mixed data? % \begin{itemize} % \item Insufficient statistics in like-sign dimuon data % \end{itemize} % \item Does the mixed data accurately reflect the coincidence background? % \end{itemize} % \begin{center} % \includegraphics[width=\textwidth]{combinatorial_background} % \end{center} % %\column{0.35\textwidth} % %\includegraphics[width=\textwidth]{e906_prediction_10103708} % %\end{columns} %\end{frame} % %\begin{frame}{Rate dependence} % %\begin{columns} % %\column{0.65\textwidth} % \begin{itemize} % \item Main Injector shows strong bunch-by-bunch intensity variations: beam intensity monitor vetoes high-intensity buckets and records event-by-event intensity % \item At high occupancies, we lose chamber hit efficiency and track reconstruction efficiency % \begin{itemize} % \item We embed simulated Drell-Yan events in random-triggered data events to measure the intensity-dependent efficiency % \end{itemize} % \item There should be no coincidence background at zero intensity; coincidence ``cross-section'' should scale with intensity % \begin{itemize} % \item We can use this directly (extrapolate to zero intensity) to extract the rate of true dimuons, but at a statistical penalty % \item We can extract the coincidence background, and use it to check and normalize the mixed data % \end{itemize} % %\item Track reconstruction efficiency is much worse for high-intensity events % %\item Coincidence background increases with intensity % %\item How do we correct for these effects? % \end{itemize} % %\begin{center} % %\includegraphics[width=\textwidth]{shadowing.png} % %\end{center} % %\column{0.35\textwidth} % %\includegraphics[width=\textwidth]{e906_prediction_10103708} % %\end{columns} %\end{frame} % %%\begin{frame}{Extrapolation to zero intensity} % %\begin{columns} % %\column{0.6\textwidth} % %\begin{itemize} % %\item We could use intensity extrapolation to get the cross-sections for each target, and take ratios % %\item Since what we really want is a ratio of two cross-sections, we can extrapolate the ratio instead % %\begin{itemize} % %\item Avoid systematic effects % %\end{itemize} % %\item Working on understanding the correct functional form and treatment of errors % %\end{itemize} % %%\begin{center} % %%\includegraphics[width=\textwidth]{shadowing.png} % %%\end{center} % %\column{0.4\textwidth} % %\includegraphics[width=\textwidth]{ratio_extrapolation} % %\end{columns} %%\end{frame} % %%\begin{frame}{Extraction of coincidence background} % %\begin{columns} % %\column{0.6\textwidth} % %\begin{itemize} % %\item Correct for luminosity and efficiencies, then a linear fit vs. intensity gives us both the true dimuon and coincidence background distributions % %\item Validating this technique: % %\begin{itemize} % %\item Comparing coincidence background to mixed data % %\item Comparing true dimuon distribution to charmonia and DY Monte Carlo % %\end{itemize} % %\end{itemize} % %%\begin{center} % %%\includegraphics[width=\textwidth]{shadowing.png} % %%\end{center} % %\column{0.4\textwidth} % %\includegraphics[width=\textwidth]{intensityfitresults} % %\end{columns} %%\end{frame} % %%\begin{frame}{Analysis status and plans} %%\begin{columns} %%\column{\textwidth} %%\begin{itemize} %%\item Alignment and reconstruction: done %%\item Detector efficiency: done %%\item Trigger performance: in progress %%\item Next steps: %%\begin{itemize} %%\item Look for signal %%\item Understand our expected signal: update signal yields using as-built trigger geometry %%\end{itemize} %%\end{itemize} %%\begin{center} %%\hspace{0.1\textwidth} %%\end{center} %%\end{columns} %%\end{frame} % %\begin{frame}{The outlook for 2019} % %\begin{columns} % %\column{0.65\textwidth} % \begin{itemize} % \item E906 energy loss analysis is making good progress on the key analysis issues; we expect a result this year % \item E1039 will take first beam this year % \begin{itemize} % \item Crucial test of sea quark orbital angular momentum % \item Dark photon program continues, with first physics data for a world-leading BSM search % \item Collaborators welcome! % \end{itemize} % \end{itemize} % \begin{center} % \includegraphics[width=0.7\textwidth]{e1039_target} % \end{center} % %\column{0.35\textwidth} % %\includegraphics[width=\textwidth]{e1039_target} % % %\includegraphics[width=\textwidth]{Visible_Aprime_Future} % %\tiny{arXiv:1804.00661} % %\end{columns} %\end{frame} % % %% Detector efficiency %% Trigger efficiency? %% EMCal % %\begin{frame}{Fix vertex fit} %\begin{columns} %\column{0.6\textwidth} %\begin{itemize} %\item The resolution of the reconstructed mass should be independent of Z but is worse for displaced vertices. %\end{itemize} %\begin{center} %\includegraphics[width=\textwidth]{mass_shift_40} %\end{center} %\column{0.4\textwidth} %\includegraphics[width=\textwidth,page=4]{acceptance_40} %\end{columns} %\end{frame} \end{document}