Mono-lepton signature of a neutrino-philic dark fermion at hadron colliders

IF 2.8 3区物理与天体物理 Q2 PHYSICS, PARTICLES & FIELDS

Nuclear Physics B Pub Date : 2025-07-18 DOI:10.1016/j.nuclphysb.2025.117028

Kai Ma , Lin-Yun He

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Abstract

Searching for dark matter at high-energy colliders and direct detection experiments can effectively cover nearly the entire mass range from the MeV to the TeV scale. In this paper, we focus on four-fermion contact interactions formulated within the framework of Effective Field Theory. Specifically, we present a detailed analysis of mono-lepton production at the LHC. Our results demonstrate that tensor operators exhibit superior sensitivity in the mono-lepton channel, constraining energy scales up to 3 TeV for a nearly massless dark fermion using current LHC data. Moreover, these operators mediate both spin-independent and spin-dependent absorption processes in nuclear targets. A systematic comparison of constraints between direct detection experiments and collider measurements reveals the LHC's distinct advantage in exploring sub-GeV dark matter candidates while maintaining competitive sensitivity at the TeV scale. Notably, direct detection experiments such as Super-Kamiokande and Borexino achieve complementary constraints in the 10-100 MeV mass range through their unique capabilities: utilization of light nuclei targets, large exposure volumes, and distinctive features of the recoil energy spectra.

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强子对撞机中亲中微子暗费米子的单轻子特征

在高能对撞机上寻找暗物质和直接探测实验可以有效地覆盖从MeV到TeV尺度的几乎整个质量范围。本文主要研究有效场论框架下的四费米子接触相互作用。具体来说，我们对LHC的单轻子产生进行了详细的分析。我们的研究结果表明，张量算符在单轻子通道中表现出优越的灵敏度，使用当前LHC数据将几乎无质量的暗费米子的能量限制在3tev。此外，这些算子介导核靶中自旋独立和自旋依赖的吸收过程。对直接探测实验和对撞机测量之间的限制进行了系统的比较，揭示了大型强子对撞机在探索亚gev暗物质候选者方面的独特优势，同时在TeV尺度上保持了竞争性的灵敏度。值得注意的是，Super-Kamiokande和Borexino等直接探测实验通过其独特的能力：利用轻核目标、大曝光量和反冲能谱的独特特征，在10-100 MeV的质量范围内实现了互补约束。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nuclear Physics B 物理-物理：粒子与场物理

CiteScore

5.50

自引率

7.10%

发文量

302

审稿时长

1 months

期刊介绍： Nuclear Physics B focuses on the domain of high energy physics, quantum field theory, statistical systems, and mathematical physics, and includes four main sections: high energy physics - phenomenology, high energy physics - theory, high energy physics - experiment, and quantum field theory, statistical systems, and mathematical physics. The emphasis is on original research papers (Frontiers Articles or Full Length Articles), but Review Articles are also welcome.