Neutrino Program at Fermilab -- Enhancing proton beam power and accelerator infrastructure

arXiv - PHYS - Accelerator Physics Pub Date : 2024-07-10 DOI:arxiv-2407.08038

Ganguly SudeshnaFermilab

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Abstract

The upcoming long baseline neutrino experiments aim to enhance proton beam power to multi-MW scale and utilize large-scale detectors to address the challenge of limited event statistics. The DUNE experiment at LBNF will test the three neutrino flavor paradigm and directly search for CP violation by studying oscillation signatures in the high intensity $\nu_{\mu}$ (anti-$\nu_{\mu}$) beam to $\nu_{e}$ (anti-$\nu_{e}$) measured over a long baseline. Higher beam power and improved accelerator up-time will enhance neutrino flux for the neutrino program by increasing the number of protons on target. LBNF/DUNE, as well as PIP-II upgrade and Accelerator Complex Evolution (ACE) plan, play a vital role in this effort. The scientific potential of ACE plan extends beyond neutrino physics, encompassing endeavors such as the Muon Collider, Charged Lepton Flavor Violation (CLFV), Dark Sectors, and exploration of neutrinos beyond DUNE.\par In the era of higher-power accelerator operation , research in target materials and beam instrumentation is crucial for optimizing design modifications. This abstract discusses Fermilab ACE, the science opportunities it provides, and how Fermilab is pushing the limits of proton beam power and accelerator infrastructure. By tackling neutrino beam challenges and exploring research and development ideas, we are advancing our understanding of fundamental particles and their interactions.

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费米实验室中微子计划 -- 增强质子束功率和加速器基础设施

即将进行的长基线中微子实验旨在将质子束功率提高到多兆瓦级，并利用大型探测器来解决有限事件统计的挑战。LBNF的DUNE实验将测试三种中微子味道范式，并通过研究在长基线上测量到的高强度$\nu_{\mu}$（anti\$nu_{\mu}$）束到$\nu_{e}$（anti\$\nu_{e}$）的振荡特征，直接搜索CP违反。更高的束流功率和更好的加速器正常运行时间将通过增加目标上质子的数量来提高中微子计划的中微子通量。LBNF/DUNE 以及 PIP-II 升级和加速器综合演化（ACE）计划在这一努力中发挥着至关重要的作用。ACE计划的科学潜力超越了中微子物理，涵盖了诸如μ介子对撞机、带电质子味违反（CLFV）、暗扇区和探索DUNE以外的中微子等工作。在更高功率加速器运行的时代，靶材料和束流仪器的研究对于优化设计修改至关重要。本摘要讨论了费米实验室 ACE、它提供的科学机会以及费米实验室如何挑战质子束功率和加速器基础设施的极限。通过应对中微子束挑战和探索研发思路，我们正在推进对基本粒子及其相互作用的理解。

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arXiv - PHYS - Accelerator Physics

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