English

$\mu$TRISTAN

High Energy Physics - Phenomenology 2022-05-11 v2 High Energy Physics - Experiment

Abstract

The ultra-cold muon technology developed for the muon g2g-2 experiment at J-PARC provides a low emittance μ+\mu^+ beam which can be accelerated and used for realistic collider experiments. We consider the possibility of new collider experiments by accelerating the μ+\mu^+ beam up to 1 TeV. Allowing the μ+\mu^+ beam to collide with a high intensity ee^- beam at the TRISTAN energy, Ee=30E_{e^-}= 30 GeV, in the storage ring with the same size as TRISTAN (the circumference of 3 km), one can realize a collider experiment with the center-of-mass energy s=346\sqrt s = 346 GeV, which allows productions of the Higgs bosons through the vector boson fusion processes. We estimate the deliverable luminosity with existing accelerator technologies to be at the level of 5×10335 \times 10^{33} cm2^{-2} s1^{-1}, with which the collider can be a good Higgs boson factory. The μ+μ+\mu^+ \mu^+ colliders up to s=2\sqrt s = 2 TeV are also possible by using the same storage ring. They have a capability of producing the superpartner of the muon up to TeV masses.

Keywords

Cite

@article{arxiv.2201.06664,
  title  = {$\mu$TRISTAN},
  author = {Yu Hamada and Ryuichiro Kitano and Ryutaro Matsudo and Hiromasa Takaura and Mitsuhiro Yoshida},
  journal= {arXiv preprint arXiv:2201.06664},
  year   = {2022}
}

Comments

23 pages, 7 figures, version to appear in PTEP

R2 v1 2026-06-24T08:52:56.612Z