Abstract

A nanometer beam size at the interaction point (IP) is required for future linear colliders to achieve the desired rate of particle collisions. KEK Accelerator Test Facility 2 (ATF2), a scaled down implementation of the linear collider beam delivery system, serves for demonstrating the feasibility of the final focus system (FFS). An unprecedented low vertical beam size at the IP of about 40 nm has been already measured in ATF2 using the optics with a nominal ${\ensuremath{\beta}}_{y}^{*}$. In our study we decrease the ${\ensuremath{\beta}}_{y}^{*}$ value in order to investigate the performance of more chromatic optics and to study the limits of beam focusing at the IP. Stronger beam focusing amplifies the aberrations from the final focus imperfections which cause an increase of the beam size at the IP. Simulations show that the multipolar errors and final doublet fringe fields spoil the IP beam sizes for ultralow ${\ensuremath{\beta}}_{y}^{*}$ optics but can be mitigated either by increasing the value of the horizontal ${\ensuremath{\beta}}^{*}$ or installing a pair of octupole magnets. We report on our first experimental steps towards the ultralow ${\ensuremath{\beta}}_{y}^{*}$ in ATF2. New methods for the beam diagnostics at the IP were developed in order to precisely set the desired optics. ${\ensuremath{\beta}}_{y}^{*}$ value was half the nominal value. The beam tuning was performed and the measured beam size is compared with the simulation results.

Highlights

  • In the future linear collider (CLIC [1], ILC [2]) the high collision rate will be achieved by colliding the beams demagnified to nanometer size at the interaction point (IP)

  • Chromatic effects associated with the final doublet (FD) quadrupoles mean that off-momentum particles are not focused exactly at the focal point, leading to larger spot sizes at the IP

  • It has already been demonstrated that the IP vertical beam size in Accelerator Test Facility 2 (ATF2) decreases from some hundreds of nanometers to about 40 nm [6,7,8] when the chromaticity is corrected

Read more

Summary

INTRODUCTION

In the future linear collider (CLIC [1], ILC [2]) the high collision rate will be achieved by colliding the beams demagnified to nanometer size at the interaction point (IP). For CLIC the expected level of chromaticity is higher by about a factor 5 For this reason, the ultralow βÃy optics [9,10,11] are being carried out at ATF2 with the aim of increasing the level of chromaticity. In principle, lowering the βÃy value allows IP beam sizes closer to those of a future linear collider to be reached. Magnetic imperfections such as multipolar errors [11] and fringe fields [12] may limit the IP beam size.

High order multipole fields and fringe fields of the ATF2 magnets
Mitigation methods
FIRST EXPERIMENTS WITH THE HALF βÃy OPTICS
Matching the beam parameters at the IP
Beam diagnostics at the IP
New method for IP vertical emittance measurement
Beam tuning and IP beam size measurements in half βÃy optics
Beam tuning simulations
38 Æ 7 49 Æ 13 62 Æ 20 46 Æ 10 54 Æ 11 55 Æ 16 74 Æ 22
Findings
CONCLUSION

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

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.