Your search keyword '"Stefano Miscetti"' showing total 7 results

1. The Mu2e Crystal Calorimeter: An Overview

Author

Nikolay Atanov, Vladimir Baranov, Leo Borrel, Caterina Bloise, Julian Budagov, Sergio Ceravolo, Franco Cervelli, Francesco Colao, Marco Cordelli, Giovanni Corradi, Yuri Davydov, Stefano Di Falco, Eleonora Diociaiuti, Simone Donati, Bertrand Echenard, Carlo Ferrari, Antonio Gioiosa, Simona Giovannella, Valerio Giusti, Vladimir Glagolev, Francesco Grancagnolo, Dariush Hampai, Fabio Happacher, David Hitlin, Matteo Martini, Sophie Middleton, Stefano Miscetti, Luca Morescalchi, Daniele Paesani, Daniele Pasciuto, Elena Pedreschi, Frank Porter, Fabrizio Raffaelli, Alessandro Saputi, Ivano Sarra, Franco Spinella, Alessandra Taffara, Anna Maria Zanetti, and Ren Yuan Zhu

Subjects

scintillation, crystals, SiPM, calorimetry, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The Mu2e experiment at Fermilab will search for the standard model-forbidden, charged lepton flavour-violating conversion of a negative muon into an electron in the field of an aluminium nucleus. The distinctive signal signature is represented by a mono-energetic electron with an energy near the muon’s rest mass. The experiment aims to improve the current single-event sensitivity by four orders of magnitude by means of a high-intensity pulsed muon beam and a high-precision tracking system. The electromagnetic calorimeter complements the tracker by providing high rejection power in muon to electron identification and a seed for track reconstruction while working in vacuum in presence of a 1 T axial magnetic field and in a harsh radiation environment. For 100 MeV electrons, the calorimeter should achieve: (a) a time resolution better than 0.5 ns, (b) an energy resolution

Published

2022

2. Mu2e Crystal Calorimeter Readout Electronics: Design and Characterisation

Author

Nikolay Atanov, Vladimir Baranov, Leo Borrel, Caterina Bloise, Julian Budagov, Sergio Ceravolo, Franco Cervelli, Francesco Colao, Marco Cordelli, Giovanni Corradi, Yuri Davydov, Stefano Di Falco, Eleonora Diociaiuti, Simone Donati, Bertrand Echenard, Carlo Ferrari, Antonio Gioiosa, Simona Giovannella, Valerio Giusti, Vladimir Glagolev, Francesco Grancagnolo, Dariush Hampai, Fabio Happacher, David Hitlin, Matteo Martini, Sophie Middleton, Stefano Miscetti, Luca Morescalchi, Daniele Paesani, Daniele Pasciuto, Elena Pedreschi, Frank Porter, Fabrizio Raffaelli, Alessandro Saputi, Ivano Sarra, Franco Spinella, Alessandra Taffara, Anna Maria Zanetti, and Ren-Yuan Zhu

Subjects

calorimeter, front-end, electronics, crystals, SiPM, MPPC, Physics, QC1-999, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The Mu2e experiment at Fermi National Accelerator Laboratory will search for the charged-lepton flavour-violating neutrinoless conversion of negative muons into electrons in the Coulomb field of an Al nucleus. The conversion electron with a monoenergetic 104.967 MeV signature will be identified by a complementary measurement carried out by a high-resolution tracker and an electromagnetic calorimeter, improving by four orders of magnitude the current single-event sensitivity. The calorimeter—composed of 1348 pure CsI crystals arranged in two annular disks—has a high granularity, 10% energy resolution and 500 ps timing resolution for 100 MeV electrons. The readout, based on large-area UV-extended SiPMs, features a fully custom readout chain, from the analogue front-end electronics to the digitisation boards. The readout electronics design was validated for operation in vacuum and under magnetic fields. An extensive radiation hardness certification campaign certified the FEE design for doses up to 100 krad and 1012 n1MeVeq/cm2 and for single-event effects. A final vertical slice test on the final readout chain was carried out with cosmic rays on a large-scale calorimeter prototype.

Published

2022

3. The Mu2e crystal and SiPM calorimeter: construction status

Author

Nikolay Atanov, Vladimir Baranov, Leo Borrel, Caterina Bloise, Julian Budagov, Sergio Ceravolo, Franco Cervelli, Francesco Colao, Marco Cordelli, Giovanni Corradi, Yuri Davydov, Stefano Di Falco, Eleonora Diociaiuti, Simone Donati, Bertrand Echenard, Carlo Ferrari, Ruben Gargiulo, Antonio Gioiosa, Simona Giovannella, Valerio Giusti, Vladimir Glagolev, Francesco Grancagnolo, Dariush Hampai, Fabio Happacher, David Hitlin, Matteo Martini, Sophie Middleton, Stefano Miscetti, Luca Morescalchi, Daniele Paesani, Daniele Pasciuto, Elena Pedreschi, Frank Porter, Fabrizio Raffaelli, Alessandro Saputi, Ivano Sarra, Franco Spinella, Alessandra Taffara, Anna Maria Zanetti, and Ren-Yuan Zhu

Subjects

Nuclear and High Energy Physics, Nuclear Energy and Engineering, Electrical and Electronic Engineering

Published

2023

4. Automated Test Station for the Characterization of Custom Silicon PhotoMultipliers for the Mu2e Calorimeter

Author

Morescalchi, Luca, primary, Caiulo, Davide, additional, Franco, Cervelli, additional, Stefano, Di Falco, additional, Simone, Donati, additional, Leonardo, Lucchesi, additional, Daniele, Pasciuto, additional, Elena, Pedreschi, additional, Fabrizio, Raffaelli, additional, Franco, Spinella, additional, Marco, Cordelli, additional, Gianni, Corradi, additional, Eleonora, Diociaiuti, additional, Raffaella, Donghia, additional, Simona, Giovannella, additional, Fabio, Happacher, additional, Martteo, Martini, additional, Stefano, Miscetti, additional, Marco, Ricci, additional, Ivano, Sarra, additional, Anna, Ferrari, additional, Stefan, Muller, additional, Nabil, Meena, additional, Radia, Sia, additional, and Gianantonio, Pezzullo, additional

Published

2019

5. The muon to electron conversion process and the Mu2e experiment at Fermilab

Author

Stefano Miscetti

Subjects

Physics, Nuclear physics, Muon, Orders of magnitude (time), Physics::Instrumentation and Detectors, Mu2e, Physics::Accelerator Physics, High Energy Physics::Experiment, Invariant mass, Solenoid, Fermilab, Electron, Muon capture

Abstract

The Mu2e experiment at Fermilab aims to measure the charged-lepton flavor violating (CLFV) neutrino-less conversion of a negative muon into an electron in the field of an aluminum nucleus. In the Standard Model, the CLFV processes in the muon sector have negligible rates.However, in many Beyond the Standard Model scenarios their rates are within reach of next generation experiments. Goal of the Mu2e experiment is to improve of four orders of magnitude the best previous measurement and reach a single event sensitivity of 2.5 $\times 10^{-17}$ on the conversion rate with respect to the muon capture rate. The distinctive signature of the muon to electron conversion is a mono-energetic electron with momentumvery close to the muon rest mass. In this paper, we explain the sensitivity to new physics scale and the Mu2e experimental technique that is based on four elements: the high muon intensity, the used pulsed beam structure , the extinction of out of time particles and a precise electron identification in the detector solenoid. Production and transport of the muons is done with a sophisticated magnetic system composed by a production, a transport and a detector solenoid. The experiment goal is achieved by stopping 10$^{18}$ low momentum muons on an Aluminium target in three years of running. This paper focuses on the design and status of the experiment.

Published

2017

6. Design and status of the Mu2e experiment

Author

Stefano Miscetti

Subjects

Physics, Theoretical physics, Particle physics, Upgrade, Muon, Physics beyond the Standard Model, QC1-999, Mu2e, Invariant mass, High Energy Physics::Experiment, Electron

Abstract

The Mu2e experiment aims to measure the charged-lepton flavor violating neutrino-less conversion of a negative muon into an electron in the field of an aluminum nucleus. The objective is to improve the previous measurement by four orders of magnitude with the use of a similar technique. For the conversion process, the signal will appear as a mono-energetic electron very close to the muon rest mass. In the Standard Model these process have negligible rates. However, in many Beyond the Standard Model scenarios their rates are within the reach of next generation experiments. In this paper, we explain the sensitivity to new physics scale and the complementarity of approach and reach provided by MU2E with respect to Mu3e and MEG upgrade. Mu2e experimental technique, design and status will be the focus of this paper.

Published

2016

7. The Readout Electronics of the Mu2e Electromagnetic Calorimeter

Author

Luca Morescalchi, Franco Cervelli, Stefano DiFalco, Simone Donati, Antonio Gioiosa, Daniele Pasciuto, Elena Pedreschi, Fabrizio Raffaelli, Franco Spinella, Alessandra Taffara, Sergio Ceravolo, Francesco Colao, Gianni Corradi, Eleonora Diociaiuti, Simona Giovannella, Fabio HAPPACHER, Matteo Martini, Stefano Miscetti, Daniele Paesani, and Ivano Sarra