FPF@FCC:100TeV质子对撞机的中微子、QCD和BSM物理机会

Roshan Mammen Abraham, Jyotismita Adhikary, Jonathan L. Feng, Max Fieg, Felix Kling, Jinmian Li, Junle Pei, Tanjona R. Rabemananjara, Juan Rojo, Sebastian Trojanowski
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引用次数: 0

摘要

能量前沿设施中的质子-质子对撞会产生高能轻粒子流,包括中微子。在大型强子对撞机上,这些粒子目前正通过远向实验FASER/FASER$/nu$和SND@LHC进行研究,而在HL-LHC运行的前向物理设施(FPF)的背景下,已经提出了新的专用实验。我们发现可以探测到10^9美元的电子/介子中微子和10^7美元的陶中微子,这比(HL-)大型强子对撞机的产率提高了几个数量级。我们研究了在FPF@FCC进行的中微子DIS测量对约束核子的非极化和自旋部分子结构的影响,并用质子-铅对撞中产生的中微子评估了它们对核动力学的敏感性,最小可达$x \sim 10^{-9}$。我们证明了FPF@FCC可以测量$\nu_{e}$和$\nu_\mu$的中微子电荷半径,并且达到$\nu_\tau$的SM值的五倍以下。我们对FPF@FCC的BSM灵敏度进行了指纹识别,包括暗希格斯玻色子、弛豫型方案、奇异粒子和毫冲粒子等多种模型,发现这些实验能够发现质量高达50 GeV、耦合小到10^{-8}$的LLPs,以及质量高达10 TeV的奇异粒子。我们的研究凸显了将前向实验整合到FCC项目中可能带来的非凡机遇,并为在HL-LHC的FPF提供了新的动力,作为优化前向物理实验的重要先例,这将使FCC实现其全部物理潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
FPF@FCC: Neutrino, QCD, and BSM Physics Opportunities with Far-Forward Experiments at a 100 TeV Proton Collider
Proton-proton collisions at energy-frontier facilities produce an intense flux of high-energy light particles, including neutrinos, in the forward direction. At the LHC, these particles are currently being studied with the far-forward experiments FASER/FASER$\nu$ and SND@LHC, while new dedicated experiments have been proposed in the context of a Forward Physics Facility (FPF) operating at the HL-LHC. Here we present a first quantitative exploration of the reach for neutrino, QCD, and BSM physics of far-forward experiments integrated within the proposed Future Circular Collider (FCC) project as part of its proton-proton collision program (FCC-hh) at $\sqrt{s} \simeq 100$ TeV. We find that $10^9$ electron/muon neutrinos and $10^7$ tau neutrinos could be detected, an increase of several orders of magnitude compared to (HL-)LHC yields. We study the impact of neutrino DIS measurements at the FPF@FCC to constrain the unpolarised and spin partonic structure of the nucleon and assess their sensitivity to nuclear dynamics down to $x \sim 10^{-9}$ with neutrinos produced in proton-lead collisions. We demonstrate that the FPF@FCC could measure the neutrino charge radius for $\nu_{e}$ and $\nu_\mu$ and reach down to five times the SM value for $\nu_\tau$. We fingerprint the BSM sensitivity of the FPF@FCC for a variety of models, including dark Higgs bosons, relaxion-type scenarios, quirks, and millicharged particles, finding that these experiments would be able to discover LLPs with masses as large as 50 GeV and couplings as small as $10^{-8}$, and quirks with masses up to 10 TeV. Our study highlights the remarkable opportunities made possible by integrating far-forward experiments into the FCC project, and it provides new motivation for the FPF at the HL-LHC as an essential precedent to optimize the forward physics experiments that will enable the FCC to achieve its full physics potential.
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