000197677 001__ 197677
000197677 005__ 20190316235850.0
000197677 0247_ $$2doi$$a10.5075/epfl-thesis-6046
000197677 02470 $$2urn$$aurn:nbn:ch:bel-epfl-thesis6046-8
000197677 02471 $$2nebis$$a10101203
000197677 037__ $$aTHESIS
000197677 041__ $$aeng
000197677 088__ $$a6046
000197677 245__ $$aMonte Carlo Modeling of Crystal Channeling at High Energies
000197677 269__ $$a2014
000197677 260__ $$aLausanne$$bEPFL$$c2014
000197677 336__ $$aTheses
000197677 502__ $$aProf. F. Mila (président), Prof. L. Rivkin, Dr F. Cerutti (directeurs),  Dr C. Bracco, Dr S. Redaelli, Dr M. Seidel (rapporteurs)
000197677 520__ $$aCharged particles entering a crystal close to some preferred direction can be trapped in the electromagnetic potential well existing between consecutive planes or strings of atoms. This channeling effect can be used to extract beam particles if the crystal is bent beforehand. Crystal channeling is becoming a reliable and efficient technique for collimating beams and removing halo particles. At the European Organization for Nuclear Research (CERN), the installation of silicon crystals in the Large Hadron Collider (LHC) is under scrutiny by the UA9 collaboration with the goal of investigating if they are a viable option for the collimation system upgrade. This thesis describes a new Monte Carlo model of planar channeling which has been developed from scratch in order to be implemented in the FLUKA code simulating particle transport and interactions. Crystal channels are described through the concept of continuous potential taking into account thermal motion of the lattice atoms and using Moliere screening function. The energy of the particle transverse motion determines whether or not it is trapped between the crystal planes while single Coulomb scattering on lattice atoms can lead to dechanneling. The volume capture and reflection applying to quasi-channeled particles are also modeled. Analogously to dechanneling, single scattering is used to determine the occurrence of volume capture. The parameters of the crystals, such as torsion or miscut, are described as well. For channeled particles, the suppression of electromagnetic and nuclear collisions is implemented. It is stronger for particles oscillating close to the center of the channel and is crucial for a correct evaluation of the rate of dechanneling without having recourse to the use of a macroscopic dechanneling length. The UA9-H8 experiment conducted at CERN aims at investigating new crystal physics as well as characterizing crystals that can be of interest in view of the implementation of crystal collimation at CERN, including in the LHC. This experiment uses silicon strip detectors situated on both sides of the crystal. Putting together upstream and downstream tracks in coincidence and matching at an identical fitted location on the crystal, it yields information about the deflections given to the beam population. Several runs from the UA9-H8 experiment are analyzed and compared to the model results. Channeling and dechanneling rates, as well as angular distributions at crystal exit are shown to be in a very encouraging agreement both for strip and quasi-mosaic crystals.
000197677 6531_ $$acrystal
000197677 6531_ $$achanneling
000197677 6531_ $$aMonte Carlo
000197677 6531_ $$aFluka
000197677 6531_ $$avolume reflection
000197677 6531_ $$avolume capture
000197677 6531_ $$aMolière potential
000197677 6531_ $$acrystal-assisted collimation
000197677 700__ $$0245847$$aSchoofs, Philippe Jean$$g197127
000197677 720_2 $$0244707$$aRivkin, Leonid$$edir.$$g173996
000197677 720_2 $$aCerutti, Francesco$$edir.
000197677 8564_ $$s39969693$$uhttps://infoscience.epfl.ch/record/197677/files/EPFL_TH6046.pdf$$yn/a$$zn/a
000197677 909C0 $$0252363$$pLPAP$$xU10658
000197677 909CO $$ooai:infoscience.tind.io:197677$$pthesis-bn2018$$pDOI$$pSB$$pthesis$$qDOI2$$qGLOBAL_SET
000197677 917Z8 $$x108898
000197677 917Z8 $$x108898
000197677 917Z8 $$x108898
000197677 918__ $$aSB$$cIPEP$$dEDPY
000197677 919__ $$aLPAP
000197677 920__ $$a2014-3-18$$b2014
000197677 970__ $$a6046/THESES
000197677 973__ $$aEPFL$$sPUBLISHED
000197677 980__ $$aTHESIS