Constraining gluonic contact interaction of a neutrino-philic dark fermion at hadron colliders and direct detection experiments

IF 5 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Physics of the Dark Universe Pub Date : 2025-04-25 DOI:10.1016/j.dark.2025.101933

Kai Ma, Lin-Yun He

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Abstract

Weakly interacting fermions with the Standard Model particles are promising candidates for the dark matter. In this paper, we study signatures of the gluonic interactions of a dark fermion and a neutrino at hadron colliders and direct detection experiments. The lowest order interactions are described by contact operators in dimension 7. At hadron colliders, the mono-jet production is the most sensitive channel. And these operators can also induce both spin-independent and spin-dependent absorption of the dark fermion at nuclear targets. We show that for a nearly massless dark fermion, the energy scales are constrained to be higher than 500 GeV and 1.2 TeV by the current LHC and HE-LHC searches, respectively. Furthermore, we also find that almost all the parameter space accessible by the spin-independent absorption has been excluded by the current LHC constraints. In contrast, for spin-dependent absorption at light nuclear targets there is still some parameter space which cannot be reached by current and upcoming LHC searches.

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强子对撞机中亲中微子暗费米子的约束胶子接触相互作用及直接探测实验

与标准模型粒子弱相互作用的费米子有望成为暗物质的候选者。本文研究了暗费米子与中微子在强子对撞机上胶子相互作用的特征，并进行了直接探测实验。最低阶相互作用用7维的接触算子来描述。在强子对撞机中，单射流的产生是最敏感的通道。并且这些算子还可以在核目标处诱导暗费米子的自旋独立和自旋依赖吸收。我们表明，对于几乎没有质量的暗费米子，目前LHC和HE-LHC的搜索分别限制了能量尺度高于500 GeV和1.2 TeV。此外，我们还发现，几乎所有可由自旋无关吸收获得的参数空间都被当前的LHC约束所排除。相比之下，对于轻核目标的自旋依赖吸收，仍然存在一些当前和即将进行的LHC搜索无法达到的参数空间。

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

Physics of the Dark Universe ASTRONOMY & ASTROPHYSICS-

CiteScore

9.60

自引率

7.30%

发文量

118

审稿时长

61 days

期刊介绍： Physics of the Dark Universe is an innovative online-only journal that offers rapid publication of peer-reviewed, original research articles considered of high scientific impact. The journal is focused on the understanding of Dark Matter, Dark Energy, Early Universe, gravitational waves and neutrinos, covering all theoretical, experimental and phenomenological aspects.