On the sensitivity of present direct detection experiments to WIMP–quark and WIMP–gluon effective interactions: A systematic assessment and new model–independent approaches

Assuming for Weakly Interacting Massive Particles (WIMPs) a Maxwellian velocity distribution in the Galaxy we provide an assessment of the sensitivity of existing Dark Matter (DM) direct detection (DD) experiments to operators up to dimension 7 of the relativistic effective field theory describing d...

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Bibliographic Details
Published in:Astroparticle physics 2020-01, Vol.114, p.80-91
Main Authors: Kang, Sunghyun, Scopel, Stefano, Tomar, Gaurav, Yoon, Jong–Hyun
Format: Article
Language:English
Subjects:
Dark matter
Direct detection
Effective theories
Weakly interacting massive particles
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Summary:Assuming for Weakly Interacting Massive Particles (WIMPs) a Maxwellian velocity distribution in the Galaxy we provide an assessment of the sensitivity of existing Dark Matter (DM) direct detection (DD) experiments to operators up to dimension 7 of the relativistic effective field theory describing dark matter interactions with quarks and gluons. In particular we focus on a systematic approach, including an extensive set of experiments and large number of couplings, both exceeding for completeness similar analyses in the literature. The relativistic effective theory requires to fix one coupling for each quark flavor, so in principle for each different combination the bounds should be recalculated starting from direct detection experimental data. To address this problem we propose an approximate model–independent procedure that allows to directly calculate the bounds for any combination of couplings in terms of model–independent limits on the Wilson coefficients of the non–relativistic theory expressed in terms of the WIMP mass and of the neutron–to–proton coupling ratio cn/cp. We test the result of the approximate procedure against that of a full calculation, and discuss its possible pitfalls and limitations. We also provide a simple interpolating interface in Python that allows to apply our method quantitatively.
ISSN:0927-6505
1873-2852
DOI:10.1016/j.astropartphys.2019.07.001