Energy recovery twin linear e+e-, e-e- colliders (ERLC ) with high luminosities and accelerating gradients

Abstract

A recently proposed superconducting linear collider with energy recovery (ERLC) and multiple beam reuse employs twin RF structures to eliminate parasitic collisions in the linacs. Such a collider can operate in either pulsed or continuous-wave (CW) mode, achieving a luminosity of O(1036) cm-2s-1 at 2E0 = 250--500 GeV. This paper demonstrates that in pulsed mode, the ERLC luminosity is independent of the accelerating gradient for a fixed total power, enabling operation at the highest available gradients. A similar independence holds for the CW mode when the available power significantly exceeds the operational threshold. The luminosity scales with the cavity quality factor as L Q01/2. We also present, for the first time, a study of a twin e-e- ERLC and estimate its performance. This configuration is simpler than the e+e- version as it eliminates the need for beam recirculation; electrons can be generated anew for each cycle. In this case, the luminosity scales as L Q01/4. Furthermore, the use of traveling-wave (TW) RF structures allows for higher gradients and reduced thermal loading. We show that an ERLC with G = 40 MeV/m can operate in CW mode, reaching luminosities of Le+e-= (1-2.5)× 1036 and Le-e-= (3-7)× 1036 cm-2s-1 at 2E0 = 250 and 500 GeV, respectively, with a total power consumption of 150-300 MW. These results position the ERLC as a highly promising candidate for a future Higgs factory.