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SHiP Internal Notes

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2025-02-11
22:08
Consequence of replacing the mylar of the strawtubes by aluminium / Van Herwijnen, Eric (Imperial College (GB)) ; Golutvin, Andrei (Imperial College (GB)) ; Dijkstra, Hans (CERN) /SHiP Collaboration
CERN-SHiP-INT-2025-001.- Geneva : CERN, 2025

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2024-12-18
16:14
Estimation of $\mu$ combinatorial background at ECN3 / Petridis, Konstantinos (University of Bristol (GB)) ; Marshall, Alex (University of Bristol (GB)) /SHiP Collaboration
CERN-SHiP-INT-2024-002.- Geneva : CERN, 2024 Draft note on combinatorial background: PDF;

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2024-10-01
17:19
Signal and background studies for ECN3 / Bezshyiko, Iaroslava (University of Zurich (CH)) ; Lantwin, Oliver (University Federico II and INFN, Naples (IT)) ; Ovchynnikov, Maksym (CERN) ; Reghunath, Anupama (Humboldt University of Berlin (DE)) /SHiP Collaboration
In this report, we summarize physics studies performed for the SHiP experiment: neutrino deep-inelastic scattering background, muon deep-inelastic scattering background, and sensitivity to new physics particles. The report contains research work carried out up to summer 2024. [...]
CERN-SHiP-INT-2024-001.- Geneva : CERN, 2024 Note describing signal and background studies for ECN3: PDF;

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2022-05-17
15:15
Full simulation and performance of a standard iron warm muon shield with tuned return yoke / Ferro-Luzzi, Massimiliano (CERN) /SHiP collaboration
A normal-conducting magnet design of the muon shield has been proposed as an alternative to the current baseline design based on grain-oriented steel. It is based on warm magnets made with standard iron and the return yoke legs are tuned (interleaved with non-magnetic steel or brass) such as to optimize its effect on low momentum muons. [...]
CERN-SHiP-INT-2022-007.- Geneva : CERN, 2022 main document 3 aug 2022: PDF;

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2022-05-12
08:53
A possible yokeless superconducting dipole for the SHiP muonshield / Koratzinos, m (Massachusetts Inst. of Technology (US)) ; Van Herwijnen, Eric (National University of Science and Technology "MISIS" (RU)) /SHiP collaboration
We describe the use of a superconducting Canted Cosine Theta (CCT) magnet as an alternative for the baseline warm magnet for the muon shield. The conductor of the CCT magnet ensures an excellent field quality with a gentle return field. [...]
CERN-SHiP-INT-2022-006.- Geneva : CERN, 2022 Fulltext: PDF;

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2022-05-11
15:26
Preliminary exploration of a superconducting muon shield / Ferro-Luzzi, Massimiliano (CERN) /SHiP collaboration
The current baseline design of the muon shield is based on warm magnets. In contrast, this note reports on muon background simulation results of a preliminary exploration into the possibility to use superconducting magnets. [...]
CERN-SHiP-INT-2022-005.- Geneva : CERN, 2022 main document 3 aug 2022: PDF;

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2022-05-11
15:16
Normal-conducting muon shield with standard yoke iron and tuned return yoke ; first performance assessment / Wertelaers, Piet (CERN) /SHiP collaboration
A muon deflecting complex with only warm magnets has always been the baseline. But here, we have a first look at a concept based on traditional engineering, i.e [...]
CERN-SHiP-INT-2022-004.- Geneva : CERN, 2022 Fulltext: PDF;

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2022-05-11
15:14
Muon shield concept based on superconducting magnet and tuned iron return yoke / Wertelaers, Piet (CERN) /SHiP collaboration
Deterministic muon tracing seems to indicate that good deflection performance can be obtained from a train of magnetized Hadron Stopper and superconducting Main Magnets, the second of which is of reversed polarity. However, the wide range of low-momentum muon start rapidities, forces us into a wide and high design..
CERN-SHiP-INT-2022-003.- Geneva : CERN, 2022 Fulltext: PDF;

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2022-01-19
12:48
Deterministic trace computation of charged particle in three dimensions / Wertelaers, Piet (CERN) /SHiP collaboration
Establishing the curved trajectory of a charged particle in a magnetic field, becomes a stochastic affair as soon as the particle interacts with material, and then, Monte Carlo simulation is the traditional computational method. Here, we develop a deterministic competitor. [...]
CERN-SHiP-INT-2022-002.- Geneva : CERN, 2022 CERN-SHiP-INT-2022-002_version2022-03-01: PDF; CERN-SHiP-INT-2022-002_version2024-08-15: PDF;

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2022-01-12
12:21
How the distance of the cavern walls affects the background rates / Ferro-Luzzi, Massimiliano (CERN) /SHiP collaboration
The muon shield of the Beam Dump Facility splits the spurious muons from the target into two prominent plumes left and right of the SHiP experiment. A large fraction of these muons interact with the cavern walls. [...]
CERN-SHiP-INT-2022-001.- Geneva : CERN, 2022 main document: PDF;

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