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Low-Energy Radon Backgrounds from Electrode Grids in Dual-Phase Xenon TPCs

Title:	Low-Energy Radon Backgrounds from Electrode Grids in Dual-Phase Xenon TPCs
Authors:	Akerib, D. S.; Musalhi, A. K. Al; Alder, F.; Almquist, B. J.; Alsum, S.; Amarasinghe, C. S.; Ames, A.; Anderson, T. J.; Angelides, N.; Araújo, H. M.; Armstrong, J. E.; Arthurs, M.; Bai, X.; Baker, A.; Balajthy, J.; Balashov, S.; Bang, J.; Bargemann, J. W.; Barillier, E. E.; Baxter, A.; Beattie, K.; Benson, T.; Bernard, E. P.; Bernstein, A.; Bhatti, A.; Biesiadzinski, T. P.; Birch, H. J.; Bishop, E.; Blockinger, G. M.; Boulton, E. M.; Boxer, B.; Brew, C. A. J.; Brás, P.; Burdin, S.; Byram, D.; Carmona-Benitez, M. C.; Carter, M.; Chan, C.; Chawla, A.; Chen, H.; Chin, Y. T.; Chott, N. I.; Contreras, S.; Converse, M. V.; Coronel, R.; Cottle, A.; Cox, G.; Curran, D.; Cutter, J. E.; Dahl, C. E.; Darlington, I.; Dave, S.; David, A.; Delgaudio, J.; Dey, S.; de Viveiros, L.; Di Felice, L.; Ding, C.; Dobson, J. E. Y.; Druszkiewicz, E.; Dubey, S.; Dunbar, C. L.; Eriksen, S. R.; Fan, A.; Fearon, N. M.; Fieldhouse, N.; Fiorucci, S.; Flaecher, H.; Fraser, E. D.; Fruth, T. M. A.; Gaemers, P. W.; Gaitskell, R. J.; Geffre, A.; Genovesi, J.; Ghag, C.; Ghamsari, J.; Ghosh, A.; Ghosh, S.; Gibbons, R.; Gilchriese, M. G. D.; Gokhale, S.; Green, J.; van der Grinten, M. G. D.; Gwilliam, C.; Haiston, J. J.; Hall, C. R.; Hall, T.; Hampp, R. H; Hartigan-O'Connor, E.; Haselschwardt, S. J.; Hernandez, M. A.; Hertel, S. A.; Hogan, D. P.; Homenides, G. J.; Horn, M.; Huang, D. Q.; Hunt, D.; Ignarra, C. M.; Jacobsen, R. G.; Jacquet, E.; Jahangir, O.; James, R. S.; Jenkins, K.; Ji, W.; Kaboth, A. C.; Kamaha, A. C.; Kamdin, K.; Kannichankandy, M. K.; Kazkaz, K.; Khaitan, D.; Khazov, A.; Kim, J.; Kim, Y. D.; Kingston, J.; Kodroff, D.; Korolkova, E. V.; Kraus, H.; Kravitz, S.; Kreczko, L.; Kudryavtsev, V. A.; Lawes, C.; Leason, E.; Leonard, D. S.; Lesko, K. T.; Levy, C.; Liao, J.; Lin, J.; Lindote, A.; Linehan, R.; Lippincott, W. H.; Long, J.; Lopes, M. I.; Lorenzon, W.; Lu, C.; Luitz, S.; Ma, W.; Mahajan, V.; Majewski, P. A.; Manalaysay, A.; Mannino, R. L.; Marangou, N.; Matheson, R. J.; Maupin, C.; McCarthy, M. E.; McDowell, G.; McKinsey, D. N.; McLaughlin, J.; McLaughlin, J. B.; McMonigle, R.; Mei, D. -M.; Mitra, B.; Mizrachi, E.; Monzani, M. E.; Morå, K.; Morad, J. A.; Morrison, E.; Mount, B. J.; Murdy, M.; Murphy, A. St. J.; Naylor, A.; Nehrkorn, C.; Nelson, H. N.; Neves, F.; Nguyen, A.; Nilima, A.; O'Brien, C. L.; O'Shea, F. H.; Olcina, I.; Oliver-Mallory, K. C.; Orpwood, J.; Oyulmaz, K. Y; Palladino, K. J.; Pannifer, N. J.; Parveen, N.; Patton, S. J.; Penning, B.; Pereira, G.; Perry, E.; Pershing, T.; Piepke, A.; Poudel, S. S.; Qie, Y.; Reichenbacher, J.; Rhyne, C. A.; Riffard, Q.; Rischbieter, G. R. C.; Ritchey, E.; Riyat, H. S.; Rosero, R.; Rossiter, P.; Rowe, N. J.; Rushton, T.; Rynders, D.; Saltão, S.; Santone, D.; Sazzad, A. B. M. R.; Schnee, R. W.; Sehr, G.; Shafer, B.; Shaw, S.; Sherman, W.; Shi, K.; Shutt, T.; Silva, C.; Sinev, G.; Siniscalco, J.; Slivar, A. M.; Smith, R.; Softley-Brown, A. M.; Solmaz, M.; Solovov, V. N.; Sorensen, P.; Soria, J.; Stevens, A.; Sumner, T. J.; Swain, A.; Swanson, N.; Szydagis, M.; Taylor, D. J.; Taylor, R.; Taylor, W. C.; Tennyson, B. P.; Terman, P. A.; Tiedt, D. R.; Timalsina, M.; To, W. H.; Tong, Z.; Tovey, D. R.; Tranter, J.; Trask, M.; Trengove, K.; Tripathi, M.; Tvrznikova, L.; Utku, U.; Usón, A.; Vacheret, A.; Vaitkus, A. C.; Valentino, O.; Velan, V.; Wang, A.; Wang, J. J.; Wang, Y.; Webb, R. C.; Weeldreyer, L.; White, J. T.; Whitis, T. J.; Wild, K.; Williams, M.; Winnicki, J.; Witherell, M. S.; Wolf, L.; Wolfs, F. L. H.; Woodford, S.; Woodward, D.; Wright, C. J.; Xia, Q.; Xiang, X.; Xu, J.; Xu, Y.; Yeh, M.; Yeum, D.; Young, J.; Zha, W.; Zhang, C.; Zhang, H.; Zhang, T.; Zhou, Y.
Publication Year:	2026
Collection:	ArXiv.org (Cornell University Library)
Subject Terms:	High Energy Physics - Experiment; Instrumentation and Methods for Astrophysics; Instrumentation and Detectors
Description:	The dual-phase xenon time projection chamber (TPC) is a powerful technology to detect rare interactions such as scatters of dark matter particles on nuclei. In particular, the built-in gain of ionization signals in a dual-phase TPC makes it sensitive to events in the few-electron regime, as expected from low-mass dark matter interactions. The pursuit of this low-energy sensitivity through ionization-only signal detection has so far been hindered by excessive electron backgrounds observed across experiments. Much of this background is attributed to the plate-out of $^{222}$Rn decay chain isotopes on the high voltage electrode grid surfaces that span the full cross section of the TPC. This work presents a first-principle model constructed for this background, the predictions of which are consistent with data from the LZ and LUX experiments. We then discuss mitigation strategies of this background in future dual-phase TPCs and the possibility of applying this grid background model to ionization-only dark matter searches. ; 16 pages main text, 22 pages overall, 10 figures
Document Type:	text
Language:	unknown
Relation:	http://arxiv.org/abs/2602.21177
Availability:	http://arxiv.org/abs/2602.21177
Accession Number:	edsbas.215A380F
Database:	BASE