Muon detection in electron-positron annihilation for muon collider studies

F Iacoangeli,G Ballerini ,G Cotto,A Triossi,C Biino,Oscar Blanco-García ,M Bauce,R Rossin,F Anulli,Gianmario Cesarini ,M Prest,A Cappati,Francesco Collamati ,F Gonella,V Mascagna,N Pastrone,M Pelliccioni,M Antonelli,M Casarsa,Fausto Casaburo ,N Amapane,C Brizzolari,M Soldani,A Bertolin,L Sestini,O Sans Planell,M Rotondo,G Cavoto,М Иафрати ,B Ponzio,E Vallazza,Bilal Kiani ,M Zanetti,J Pazzini,L Bandiera,R Di Nardo,M Boscolo,D Lucchesi,M Ricci,N Bartosik,S Y Hoh ,C Curatolo,S Ventura,A Paccagnella,R Li Voti,S Rosati

doi:10.1016/j.nima.2021.166129

Abstract

The investigation of the energy frontier in physics requires novel concepts for future colliders. The idea of a muon collider is very appealing since it would allow to study particle collisions at up to tens of TeV energy, while offering a cleaner experimental environment with respect to hadronic colliders. One key element in the muon collider design is the low-emittance muon production. Recently, the Low EMittance Muon Accelerator (LEMMA) collaboration has explored the muon pair production close to its kinematic threshold by annihilating 45 GeV positrons with electrons in a low Z material target. In this configuration, muons are emerging from the target with a naturally low-emittance. In this paper we describe the performance of a system, to study this production mechanism, that consists in several segmented absorbers with alternating active layers composed of fast Cherenkov detectors together with a muon identification technique based on this detector. Passive layers were made of tungsten. We collected data corresponding to muon and electron beams produced at the H2 line in the North Area of the European Organization for Nuclear Research (CERN) in September 2018.

Highlights

Exploring the high energy frontier represents a great opportunity to investigate the fundamental laws of nature
In order to validate the absorber system particle detection ability leading to the results shown in Tab. 2, a Geant4 [18, 19] based Monte Carlo (MC) simulation of particle electromagnetic interactions with matter has been developed, to compare the / Nμ− Ne− events ratio obtained in data with theoretical predictions
The knowledge of the muon production cross section close to its kinematic threshold is extremely important for a muon collider design based on this concept

Summary

Introduction

Exploring the high energy frontier represents a great opportunity to investigate the fundamental laws of nature. This requires a particle collider able to accelerate elementary particles to the highest possible energy. Previous studies claimed that a muon collider is conceivable to reach the multi–TeV energy frontier with the possibility to study Higgs boson properties [2]. Muons in a circular storage ring are emitting much less synchrotron radiation than electrons with the same energy; muons accelerated in a circular collider can reach a center-of-mass (CM) energy higher than electrons in the same ring. Reaching a small emittance is one of the crucial aspects to achieve a high luminosity in a muon collider [3]

Objectives

Methods

Findings

Conclusion