The Forward Physics Facility: Sites, Experiments, and Physics Potential

“…2). These laboratory constraints, as well as upcoming searches at the Deep Underground Neutrino Experiment [39] and the Forward Physics Facility [40], will be discussed in detail in Section 5. At low mediator masses, cosmological surveys provide the strongest constraints and future prospects [41] -see Section 3 for more detail on cosmological impacts of this BSM physics.…”

“…Two dedicated LHC neutrino experiments, FASERν [217,218] and SND@LHC [219,220], will start their operation in 2022 and observe thousands of high-energy neutrino interactions within a few years. To further increase the neutrino event rate, larger LHC neutrino experiments for the high-luminosity LHC era have been proposed as part of the Forward Physics Facility (or FPF) [40]. The proposed detectors include the emulsion-based neutrino detector FASERν, the electronic neutrino detector AdvSND, and the liquid-argon neutrino detector FLArE [221].…”

Neutrino self-interactions: A white paper

“…2). These laboratory constraints, as well as upcoming searches at the Deep Underground Neutrino Experiment [39] and the Forward Physics Facility [40], will be discussed in detail in Section 5. At low mediator masses, cosmological surveys provide the strongest constraints and future prospects [41] -see Section 3 for more detail on cosmological impacts of this BSM physics.…”

“…Two dedicated LHC neutrino experiments, FASERν [217,218] and SND@LHC [219,220], will start their operation in 2022 and observe thousands of high-energy neutrino interactions within a few years. To further increase the neutrino event rate, larger LHC neutrino experiments for the high-luminosity LHC era have been proposed as part of the Forward Physics Facility (or FPF) [40]. The proposed detectors include the emulsion-based neutrino detector FASERν, the electronic neutrino detector AdvSND, and the liquid-argon neutrino detector FLArE [221].…”

Neutrino self-interactions: A white paper

“…[95] y otros que se podrían llevar a cabo en la Forward Physics Facility (FPF) [96]) resultarán de gran en el futuro para estudiar esto con mayor detalle. La mayor cantidad de partículas producidas en una colisión hadrónica son piones, de manera que se espera que cambiar el tratamiento de las colisiones pión-aire tendrá un impacto significativo en la producción de muones, ya que este efecto se acumulará en cada generación de colisiones.…”

Interacciones fuertes y electrodébiles en medios extensos

CTEQ-TEA group updates: Photon PDF and Impact from heavy flavors in the CT18 global analysis