Simulations and measurements of beam loss patterns at the CERN Large Hadron Collider

Bruce, Roderik; Assmann, R.; Boccone, V.; Bracco, Chiara; Brügger, M.; Cauchi, Marija; Cerutti, F.; Deboy, D; Ferrari, A.; Lari, L.; Marsili, A.; Mereghetti, Alessio; Mirarchi, Daniele; Quaranta, Elena; Redaelli, Stefano; Robert‐Demolaize, G.; Rossi, A.; Salvachua, Belen; Skordis, E.; Tambasco, Claudia; Valentino, Gianluca; Weiler, T.; Vlachoudis, V.; Wollmann, Daniel

doi:10.1103/physrevstab.17.081004

Cited by 79 publications

(110 citation statements)

References 25 publications

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“…Experimentally pp and pn cross sections are within less than 2 % at the highestenergy pn data available, √ s = 30 GeV, and theoretically the agreement is expected to be even less than this, as the relevant processes are dominated by Pomeron and f 2 exchange. This approximation has also been used in previous studies of the LHC collimation system ( [4,5] and references therein), which agree with measured losses.…”

Section: Introductionsupporting

confidence: 72%

The practical Pomeron for high energy proton collimation

et al. 2016

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We present a model which describes proton scattering data from ISR to Tevatron energies, and which can be applied to collimation in high energy accelerators, such as the LHC and FCC. Collimators remove beam halo particles, so that they do not impinge on vulnerable regions of the machine, such as the superconducting magnets and the experimental areas. In simulating the effect of the collimator jaws it is crucial to model the scattering of protons at small momentum transfer t, as these protons can subsequently survive several turns of the ring before being lost. At high energies these soft processes are well described by Pomeron exchange models. We study the behaviour of elastic and single-diffractive dissociation cross sections over a wide range of energy, and show that the model can be used as a global description of the wide variety of high energy elastic and diffractive data presently available. In particular it models low mass diffraction dissociation, where a rich resonance structure is present, and thus predicts the differential and integrated cross sections in the kinematical range appropriate to the LHC. We incorporate the physics of this model into the beam tracking code MERLIN and use it to simulate the resulting loss maps of the beam halo lost in the collimators in the LHC.

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Section: Introductionsupporting

confidence: 72%

The practical Pomeron for high energy proton collimation

et al. 2016

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“…Particular attention has been paid to the impact parameter and the angular spread of particles at the first passage at the crystal. While for standard primary collimators this is not a critical parameter, as results are stable in a wide range of values up to hundreds of µm [35], for crystals the initial distribution affects significantly the channeling efficiency. Impact parameters of the order of tenths of a µm are expected in the real machine [36].…”

Section: Simulation Setupmentioning

confidence: 99%

Design and implementation of a crystal collimation test stand at the Large Hadron Collider

et al. 2017

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Future upgrades of the CERN Large Hadron Collider (LHC) demand improved cleaning performance of its collimation system. Very efficient collimation is required during regular operations at high intensities, because even a small amount of energy deposited on superconducting magnets can cause an abrupt loss of superconducting conditions (quench). The possibility to use a crystal-based collimation system represents an option for improving both cleaning performance and impedance compared to the present system. Before relying on crystal collimation for the LHC, a demonstration under LHC conditions (energy, beam parameters, etc.) and a comparison against the present system is considered mandatory. Thus, a prototype crystal collimation system has been designed and installed in the LHC during the Long Shutdown 1 (LS1), to perform feasibility tests during the Run 2 at energies up to 6.5 TeV. The layout is suitable for operation with proton as well as heavy ion beams. In this paper, the design constraints and the solutions proposed for this test stand for feasibility demonstration of crystal collimation at the LHC are presented. The expected cleaning performance achievable with this test stand, as assessed in simulations, is presented and compared to that of the present LHC collimation system. The first experimental observation of crystal channeling in the LHC at the record beam energy of 6.5 TeV has been obtained in 2015 using the layout presented (Scandale et al., Phys Lett B 758:129, 2016). First tests to measure the cleaning performance of this test stand have been carried out in 2016 and the detailed data analysis is still on-going.

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“…The particle trajectories are checked against a detailed aperture model with 10 cm longitudinal precision and the simulation output contains coordinates of all loss locations. SIXTRACK is routinely used to simulate the cleaning performance of the LHC collimation system and the results have been shown to be in very good agreement with beam loss data from the LHC [65].…”

Section: B Sixtrackmentioning

confidence: 63%

“…Another method to numerically assess the impacts during a SMPF, which accounts for both the true phase advance, the particle-matter interaction inside collimators, the full ring aperture, and all collimators, is to perform a simulation with the SIXTRACK code [61][62][63][64][65]. SIXTRACK does a thin-lens element-by-element tracking through the magnetic lattice, and it has a built-in Monte Carlo code to simulate the particle-matter interaction inside collimators.…”

Section: B Sixtrackmentioning

confidence: 99%

Calculations of safe collimator settings andβ*at the CERN Large Hadron Collider

Bruce

Assmann

Redaelli

2015

Phys. Rev. ST Accel. Beams

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The first run of the Large Hadron Collider (LHC) at CERN was very successful and resulted in important physics discoveries. One way of increasing the luminosity in a collider, which gave a very significant contribution to the LHC performance in the first run and can be used even if the beam intensity cannot be increased, is to decrease the transverse beam size at the interaction points by reducing the optical function β Ã . However, when doing so, the beam becomes larger in the final focusing system, which could expose its aperture to beam losses. For the LHC, which is designed to store beams with a total energy of 362 MJ, this is critical, since the loss of even a small fraction of the beam could cause a magnet quench or even damage. Therefore, the machine aperture has to be protected by the collimation system. The settings of the collimators constrain the maximum beam size that can be tolerated and therefore impose a lower limit on β Ã . In this paper, we present calculations to determine safe collimator settings and the resulting limit on β Ã , based on available aperture and operational stability of the machine. Our model was used to determine the LHC configurations in 2011 and 2012 and it was found that β Ã could be decreased significantly compared to the conservative model used in 2010. The gain in luminosity resulting from the decreased margins between collimators was more than a factor 2, and a further contribution from the use of realistic aperture estimates based on measurements was almost as large. This has played an essential role in the rapid and successful accumulation of experimental data in the LHC.

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Simulations and measurements of beam loss patterns at the CERN Large Hadron Collider

Cited by 79 publications

References 25 publications

The practical Pomeron for high energy proton collimation

The practical Pomeron for high energy proton collimation

Design and implementation of a crystal collimation test stand at the Large Hadron Collider

Calculations of safe collimator settings andβ*at the CERN Large Hadron Collider

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