Proportional scintillation in liquid xenon: demonstration in a single-phase liquid-only time projection chamber
The largest direct dark matter search experiments to date employ dual-phase time projection chambers (TPCs) with liquid noble gas targets. These detect both the primary photons generated by particle interactions in the liquid target, as well as proportional secondary scintillation light created by t...
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Zusammenfassung: | The largest direct dark matter search experiments to date employ dual-phase
time projection chambers (TPCs) with liquid noble gas targets. These detect
both the primary photons generated by particle interactions in the liquid
target, as well as proportional secondary scintillation light created by the
ionization electrons in a strong electric field in the gas phase between the
liquid-gas interface and the anode. In this work, we describe the detection of
charge signals in a small-scale single-phase liquid-xenon-only TPC, that
features the well-established TPC geometry with light readout above and below a
cylindrical target. In the single-phase TPC, the proportional scintillation
light (S2) is generated in liquid xenon in close proximity to 10 {\mu}m
diameter anode wires. The detector was characterized and the proportional
scintillation process was studied using the 32.1 keV and 9.4 keV signals from
83mKr decays. A charge gain factor g2 of up to (1.9 $\pm$ 0.3) PE/electron was
reached at an anode voltage 4.4 kV higher than the gate electrode 5 mm below
it, corresponding to (29 $\pm$ 6) photons emitted per ionization electron. The
duration of S2 signals is dominated by electron diffusion and approaches the
xenon de-excitation timescale for very short electron drift times. The electron
drift velocity and the longitudinal diffusion constant were measured at a drift
field of 470 V/cm. The results agree with the literature and demonstrate that a
single-phase TPC can be operated successfully. |
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DOI: | 10.48550/arxiv.2405.10687 |