Ievgen Lavrukhin scite author profile

Ievgen Lavrukhin

3Publications

71Citation Statements Received

56Citation Statements Given

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Affiliations

George Washington University, University of Michigan–Ann Arbor

Publications

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Technical Design Report for the Paul Scherrer Institute Experiment R-12-01.1: Studying the Proton "Radius" Puzzle with μp Elastic Scattering

Gilman¹,

Downie²,

Ron³

et al. 2017

Preprint

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Beam-Line FIG. 3. Implementation of detectors in the πM1 area in a Geant4 [10] simulation. The beam strikes the thin scintillator beam hodoscope and three GEM chambers, passes through a hole in the annular veto scintillator, enters the cryotarget vacuum chamber and strikes one of the targets, then exits the vacuum chamber and goes through the beam monitor. Scattered particles are detected by two symmetric spectrometers, each with two straw chambers wrapped in RF shielding and two planes of scintillator paddles.

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Timing detectors with SiPM read-out for the MUSE experiment at PSI

Rostomyan

Cline

Lavrukhin

et al. 2021

Nuclear Instruments and Methods in Physics Research Section A:

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Characterization of muon and electron beams in the Paul Scherrer Institute PiM1 channel for the MUSE experiment

Cline¹,

Lin²,

Roy³

et al. 2022

Phys. Rev. C

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The MUon Scattering Experiment, MUSE, at the Paul Scherrer Institute, Switzerland, investigates the proton charge radius puzzle, lepton universality, and two-photon exchange, via simultaneous measurements of elastic muon-proton and electron-proton scattering. The experiment uses the PiM1 secondary beam channel, which was designed for high precision pion scattering measurements. We review the properties of the beam line established for pions. We discuss the production processes that generate the electron and muon beams, and the simulations of these processes. Simulations of the π/μ/e beams through the channel using TURTLE and G4beamline are compared. The G4beamline simulation is then compared to several experimental measurements of the channel, including the momentum dispersion at the intermediate focal plane and target, the shape of the beam spot at the target, and timing measurements that allow the beam momenta to be determined. We conclude that the PiM1 channel can be used for high precision π , μ, and e scattering.

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