A linear RFQ ion trap for the Enriched Xenon Observatory

A. Odian; A. Piepke; A. Pocar; Abdurashitov; Ahmad; Ahn; Araki; B. Flatt; B. Mong; C. Hall; C. Hargrove; C. Virtue; C.Y. Prescott; Cleveland; D. Hallman; D. Mackay; D. Schenker; D. Sinclair; D.S. Leonard; Danilov; Denison; E. Baussan; Elliott; F. Juget; F. LePort; Fukuda; G. Gratta; Hampel; J. Farine; J. Hodgson; J. Wodin; J.-L. Vuilleuimier; J.-M. Vuilleuimier; K. Hall; K. O’Sullivan; K. Skarpaas; K. Wamba; L. Ounalli; M. Breidenbach; M. Green; M. Hauger; M. Montero Díez; Majorana; Marchetal; McLachlan; Michael; Minfardini; Neuhauser; P. Fierlinger; P. Weber; P.C. Rowson; Paul; R. Conley; R. DeVoe; R. Neilson; S. Waldman; V. Strickland; W. Fairbank; Y. Martin

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A linear RFQ ion trap for the Enriched Xenon Observatory

Abstract

The design, construction, and performance of a linear radio-frequency ion trap (RFQ) intended for use in the Enriched Xenon Observatory (EXO) are described. EXO aims to detect the neutrinoless double-beta decay of

^{136}

Xe to

^{136}

Ba. To suppress possible backgrounds EXO will complement the measurement of decay energy and, to some extent, topology of candidate events in a Xe filled detector with the identification of the daughter nucleus (

^{136}

Ba). The ion trap described here is capable of accepting, cooling, and confining individual Ba ions extracted from the site of the candidate double-beta decay event. A single trapped ion can then be identified, with a large signal-to-noise ratio, via laser spectroscopy.Comment: 18 pages, pdflatex, submitted to NIM

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