Abstract
Energy-frontier accelerators provide powerful tools performing high precision measurements confirming the fundamentals of the physics and broadening new research horizons. Such machines are either driven by circular or linear accelerators. The circular machines, having the centre-of-mass (CM) energy values reaching 200 GeV (for leptons) and above, experience beam energy loss and quality dilution, for example, due to synchrotron radiation, limiting the overall CM energy achievable and requiring a constant energy top-up to compensate the loss and the beam quality dilution. Linear colliders overcome these limitations, while the finite capabilities of generating high average current beams limits the luminosity. This is partially compensated by the quality of the colliding beams. In this work, we suggest a novel design of circular-linear accelerator based on the merging of the “non-emitting”, low-energy storage rings and energy recovery linear accelerators. We suggest using the recently considered dual-axis asymmetric cavities to enable the operation of such a system, and in particular the energy recovery from spent, high-intensity beams. The machine considered, under the scope of the SNOWMASS-2021 initiative, can be potentially used to reach ultimate energy frontiers in high-energy physics as well as to drive next generation light sources. The merging of circular and linear systems, and applications of dual axes cavities, should allow the maintaining of high beam quality, high luminosity, and high energy efficiency, while offering a flexible energy management and opening clear opportunity for reducing the running cost. We note that the numbers shown in the paper are for illustration purpose and can be improved further.
Highlights
Energy-frontier particle accelerators are among the most exciting, complex, challenging, and expensive research instruments [1,2,3,4,5,6]
It is based on application of low-energy, “non-emitting” (1 GeV) large (1 km radius) storage rings and two dual-axis energy recovery linacs
We suggest to use non-emitting storage rings as a drivers for Free Electron Laser (FEL) stations to broaden the application of the whole system and increase its efficiency and impact
Summary
Energy-frontier particle accelerators are among the most exciting, complex, challenging, and expensive research instruments [1,2,3,4,5,6]. In this paper we suggest a novel concept which is based on merging the advantages of the circular (capability to accumulate beams) and linear (capability to deliver good quality beams) accelerators It is based on application of low-energy, “non-emitting” (1 GeV) large (1 km radius) storage rings and two dual-axis energy recovery linacs. To overcome the challenges discussed, we suggest Circular-Linear Energy Recovery System (CLER-S), based on dual-axis, asymmetric accelerating/decelerating (A/D) cavities. This system can be used for HEP to drive a dual axis collider (CLER-C), to drive generation light sources (for example free-electron lasers (CLERFEL)), or for dual purposes. We suggest to use non-emitting storage rings as a drivers for FEL stations to broaden the application of the whole system and increase its efficiency and impact
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
