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Direct neutrino detection at the LHC opens new avenues in high-energy particle physics. The proposed Forward Physics Facility (FPF) and its experiments aim to explore dark matter, new particles, and neutrino physics.

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Area of Science:

  • High-energy particle physics
  • Neutrino physics
  • Astroparticle physics

Background:

  • Direct neutrino detection at the Large Hadron Collider (LHC) signifies a new era in particle physics.
  • Forward physics offers significant potential for groundbreaking discoveries.

Purpose of the Study:

  • To present the status and potential of the Forward Physics Facility (FPF).
  • To outline the physics case for FPF, including dark matter, new particles, neutrino physics, QCD, and astroparticle physics.
  • To summarize the designs of proposed FPF experiments.

Main Methods:

  • Extensive work on defining the FPF and its experiments.
  • Summarizing current designs for the Facility and experiments like FASER2, FASERγ2, FORMOSA, and FLArE.

Main Results:

  • The FPF has unique potential to investigate key areas of physics.
  • Several experiments (FASER2, FASERγ2, FORMOSA, FLArE) are being designed for the FPF.

Conclusions:

  • The FPF is crucial for realizing the physics potential of forward physics at the LHC.
  • The proposed experiments are designed to be timely and cost-effective.