Abstract
Detectors based upon the noble elements, especially liquid xenon as well as liquid argon, as both single- and dual-phase types, require reconstruction of the energies of interacting particles, both in the field of direct detection of dark matter (weakly interacting massive particles WIMPs, axions, etc.) and in neutrino physics. Experimentalists, as well as theorists who reanalyze/reinterpret experimental data, have used a few different techniques over the past few decades. In this paper, we review techniques based on solely the primary scintillation channel, the ionization or secondary channel available at non-zero drift electric fields, and combined techniques that include a simple linear combination and weighted averages, with a brief discussion of the application of profile likelihood, maximum likelihood, and machine learning. Comparing results for electron recoils (beta and gamma interactions) and nuclear recoils (primarily from neutrons) from the Noble Element Simulation Technique (NEST) simulation to available data, we confirm that combining all available information generates higher-precision means, lower widths (energy resolution), and more symmetric shapes (approximately Gaussian) especially at keV-scale energies, with the symmetry even greater when thresholding is addressed. Near thresholds, bias from upward fluctuations matters. For MeV-GeV scales, if only one channel is utilized, an ionization-only-based energy scale outperforms scintillation; channel combination remains beneficial. We discuss here what major collaborations use.
Highlights
The noble elements, especially xenon (Xe) and argon (Ar) as liquids, have been instrumental in the field of dark matter (DM) direct detection, focused on identifying the missing ∼25% of the mass–energy content of the universe
In the former case, Xe [1,2,3] and Ar [4,5] are each used by distinct large collaborations, and used both to search for continuous spectra, such as the approximate falling exponential expected from the traditional weakly interacting massive particle (WIMP) [6], or monoenergetic peaks expected from dark photons or bosonic super-WIMPs [7]
Enriched liquid xenon (LXe) is used by nEXO ( Enriched Xenon Observatory), a time projection chamber (TPC) but only one phase, and (Neutrino Experiment with a Xenon TPC, GXe) for the hunt for 0νββ decays. αs and heavier ions different from the medium, with properties like additional quenching, modify the E reconstruction formulae, but we will only focus on basic electron recoil (ER) and nuclear recoil (NR); other recoil types are already covered elsewhere [15,63]
Summary
The noble elements, especially xenon (Xe) and argon (Ar) as liquids, have been instrumental in the field of dark matter (DM) direct detection, focused on identifying the missing ∼25% of the mass–energy content of the universe. In the former case, Xe [1,2,3] and Ar [4,5] are each used by distinct large collaborations, and used both to search for continuous spectra, such as the approximate falling exponential expected from the traditional weakly interacting massive particle (WIMP) [6], or monoenergetic peaks expected from dark photons or bosonic super-WIMPs [7] In the latter case, argon is used in long- and short-baseline oscillation studies [8,9] and xenon in the search for neutrinoless double-beta decay, as either a liquid [10] or a gas [11]. Energy scales have been based in the past and present on the scintillation, on the ionization, and on their combination
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