Synchrotron radiation leveling at future circular hadron colliders

TL;DR

The paper proposes a novel synchrotron radiation power leveling method for future circular hadron colliders like FCC-hh, which adjusts beam energy during operation to optimize luminosity and manage heat load, enhancing key physics event rates.

Contribution

It introduces the concept of synchrotron radiation power leveling, a new operational mode to improve collider performance and physics outcomes at FCC-hh.

Findings

Increases the number of di-Higgs events by over 60%.

Allows higher luminosity without exceeding heat load limits.

Provides operational scenarios for implementing radiation power leveling.

Abstract

Luminosity leveling to limit the event pile up is a key ingredient of the LHC luminosity upgrade, the High-Luminosity LHC (HL-LHC). For a future circular hadron collider, such as the FCC-hh, operating at a centre-of-mass energy of 70-90 TeV, synchrotron radiation becomes significant, with radiation damping times of the order of one or a few hours. The rapid shrinkage of the emittance may call for a leveling of the beam-beam tune shift or of the event pile up, as previously explored. However, the strong synchrotron radiation emitted inside the cold superconducting magnets also represents a significant heat load and is likely to limit the total beam current. In this article, we discuss a new approach, namely synchrotron radiation power leveling, where the beam energy is adjusted during a physics store, either continually or in a few discrete steps, while the beam current decreases, so as to keep the synchrotron radiation power at or below a certain limiting value. In this way, both peak and integrated luminosity of the FCC-hh are increased, compared with operation at a fixed beam energy. The FCC-hh detectors, and in particular the physics event analysis, need to be prepared for this novel mode of operation. This article presents two example running scenarios for synchrotron radiation leveling at the FCC-hh. While not greatly reducing the integrated luminosity at highest collision energy, synchrotron-radiation leveling can significantly increase the number of events for key processes already occurring at lower energy. As an example, we show that it raises the number of di-Higgs production events by 60% or more.