Observations of Beam Losses Due to Bound-Free Pair Production in a Heavy-Ion Collider

Bruce, Roderik; Jowett, John; Gilardoni, S.; Drees, A.; Fischer, W.; Tepikian, S.; Klein, S. R.

doi:10.1103/physrevlett.99.144801

Cited by 38 publications

(31 citation statements)

References 8 publications

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“…58 so that the measurements in Ref. [24] were only possible with 63 Cu 29þ beams and not the more usual 197 Au 79þ . Ions created by EMD1 are lost if A 0 166, meaning that this might be a source of localized losses during future collisions between lighter ions.…”

Section: Optical Trackingmentioning

confidence: 99%

Beam losses from ultraperipheral nuclear collisions betweenPb82+208ions in the Large Hadron Collider and their alleviation

Bruce

Bocian

Gilardoni

et al. 2009

Phys. Rev. ST Accel. Beams

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Electromagnetic interactions between colliding heavy ions at the Large Hadron Collider (LHC) at CERN will give rise to localized beam losses that may quench superconducting magnets, apart from contributing significantly to the luminosity decay. To quantify their impact on the operation of the collider, we have used a three-step simulation approach, which consists of optical tracking, a Monte Carlo shower simulation, and a thermal network model of the heat flow inside a magnet. We present simulation results for the case of 208 Pb 82þ ion operation in the LHC, with focus on the ALICE interaction region, and show that the expected heat load during nominal 208 Pb 82þ operation is 40% above the quench level. This limits the maximum achievable luminosity. Furthermore, we discuss methods of monitoring the losses and possible ways to alleviate their effect.

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Section: Optical Trackingmentioning

confidence: 99%

Beam losses from ultraperipheral nuclear collisions betweenPb82+208ions in the Large Hadron Collider and their alleviation

Bruce

Bocian

Gilardoni

et al. 2009

Phys. Rev. ST Accel. Beams

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“…The GDR cross section is about 2=3 of the total Coulomb excitation cross section [15]. At RHIC, these ions will lose their collimation (i.e., spread out) before striking the beam pipe and so will distribute their energy around the accelerator ring [27]. At the LHeC, they will strike the beam pipe in a well-defined location.…”

mentioning

confidence: 99%

Heavy ion beam loss mechanisms at an electron-ion collider

Klein

2014

Phys. Rev. ST Accel. Beams

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There are currently several proposals to build a high-luminosity electron-ion collider, to study the spin structure of matter and measure parton densities in heavy nuclei, and to search for gluon saturation and new phenomena like the colored glass condensate. These measurements require operation with heavy nuclei. We calculate the cross sections for two important processes that will affect accelerator and detector operations: bound-free pair production and Coulomb excitation of the nuclei. Both of these reactions have large cross sections, 28-56 mb, which can lead to beam ion losses, produce beams of particles with altered charge:mass ratio, and produce a large flux of neutrons in zero degree calorimeters. The loss of beam particles limits the sustainable electron-ion luminosity to levels of several times 10 32 =cm 2 =s.

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“…The loss of a secondary Cu 28+ beam with a higher value of δ (Eq. 12), created by BFPP1, could be observed for the first time 141 m from the interaction point of a high-luminosity experiment with especially installed PIN diodes [84]. Because of the much smaller cross section in this case, the deposited energy did not create any operational problem.…”

Section: For Comparison In Rhic Aumentioning

confidence: 74%

Ion Colliders

Fischer

Jowett

2014

Rev. Accl. Sci. Tech.

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High-energy ion colliders are large research tools in nuclear physics to study the QuarkGluon-Plasma (QGP). The range of collision energy and high luminosity are important design and operational considerations. The experiments also expect flexibility with frequent changes in the collision energy, detector fields, and ion species. Ion species range from protons, including polarized protons in RHIC, to heavy nuclei like gold, lead and uranium. Asymmetric collision combinations (e.g. protons against heavy ions) are also essential. For the creation, acceleration, and storage of bright intense ion beams, limits are set by space charge, charge change, and intrabeam scattering effects, as well as beam losses due to a variety of other phenomena. Currently, there are two operating ion colliders, the Relativistic Heavy Ion Collider (RHIC) at BNL, and the Large Hadron Collider (LHC) at CERN.

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Observations of Beam Losses Due to Bound-Free Pair Production in a Heavy-Ion Collider

Cited by 38 publications

References 8 publications

Beam losses from ultraperipheral nuclear collisions betweenPb82+208ions in the Large Hadron Collider and their alleviation

Beam losses from ultraperipheral nuclear collisions betweenPb82+208ions in the Large Hadron Collider and their alleviation

Heavy ion beam loss mechanisms at an electron-ion collider

Ion Colliders

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