Abstract
The Mu2e experiment being designed at Fermilab will be searching for a rare event - conversion of muon into electron in the field of a nucleus without emission of neutrinos - observation of which would provide unambiguous evidence for physics beyond the Standard Model, making use of an 8 GeV 8 kW proton beam. As an experiment to be performed at the Intensity Frontier, taking advantage of high-intensity proton beams, the Mu2e experimental setup will be residing in a harsh radiation environment created by secondary particle fluxes. Radiation quantities in different parts of the Mu2e apparatus, such as neutron flux, peak power density, displacements per atom (DPA), absorbed dose, dynamic heat load simulated using the MARS15 code are reviewed in this work. Radiation levels and requirements for Heat and Radiation Shield (HRS), Transport Solenoid (TS), residual dose and decay heat from the Mu2e target, beam dump design, rates in Cosmic Ray Veto (CRV) counters as well as stopping target monitor (STM) are considered. Airflow, surface and ground water activation are estimated. Recent developments in the MARS15 DPA model applied in this work are described, their consequences are discussed.
Original language | English |
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Article number | 1330014 |
Journal | Modern Physics Letters A |
Volume | 28 |
Issue number | 19 |
DOIs | |
State | Published - Jun 21 2013 |
Externally published | Yes |
Keywords
- Monte Carlo simulations
- Muon to electron conversion
- apparatus design
- energy deposition
- neutron background
- radiation damage