Abstract
The integrated luminosity, a key figure of merit for any particle-physics collider, is closely linked to the peak luminosity and to the beam lifetime. The instantaneous peak luminosity of a collider is constrained by a number of boundary conditions, such as the available beam current, the maximum beam-beam tune shift with acceptable beam stability and reasonable luminosity lifetime (i.e., the empirical ``beam-beam limit''), or the event pileup in the physics detectors. The beam lifetime at high-luminosity hadron colliders is largely determined by particle burn off in the collisions. In future highest-energy circular colliders synchrotron radiation provides a natural damping mechanism, which can be exploited for maximizing the integrated luminosity. In this article, we derive analytical expressions describing the optimized integrated luminosity, the corresponding optimum store length, and the time evolution of relevant beam parameters, without or with radiation damping, while respecting a fixed maximum value for the total beam-beam tune shift or for the event pileup in the detector. Our results are illustrated by examples for the proton-proton luminosity of the existing Large Hadron Collider (LHC) at its design parameters, of the High-Luminosity Large Hadron Collider (HL-LHC), and of the Future Circular Collider (FCC-hh).
Highlights
Five hadron colliders have been in operation [Intersecting Storage Rings (ISR), Super Proton Synchrotron (Spp S), Tevatron, Relativistic Heavy Ion Collider (RHIC), and Large Hadron Collider (LHC)]
If we take the dominant source of beam loss to be due to the burn-off in collision, the rate of change of the bunch intensity is proportional to the instantaneous luminosity as dNb dt where σtot denotes the total cross section, and L the luminosity at each interaction point (IP), and, for later use, we have introduced the parameter K: K
For the High-Luminosity Large Hadron Collider (HL-LHC) target parameters in Table I, we find tdec;opt ≈ 3.34 h
Summary
Five hadron colliders have been in operation [Intersecting Storage Rings (ISR), Super Proton Synchrotron (Spp S), Tevatron, Relativistic Heavy Ion Collider (RHIC), and LHC]. During operation the peak luminosity will be controlled and reduced (“luminosity leveling”) in order to sustain the operational luminosity, and the associated event pileup, at a constant level over a significant length of time [41,42,43] This luminosity leveling during a physics store can be accomplished in a number of ways [41,42,43,97]: (i) dynamic βà squeeze, (ii) crossing angle variation, (iii) changes in the crab rf voltage, including the elegant “crab kissing” scheme [60], (iv) dynamic bunch-length reduction, or (v) controlled variation of the transverse distance between the two colliding beams. With an availability as low as 40% and considering 160 days scheduled for physics per calendar year, the luminosity delivered per year will exceed 250 fb−1
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