F.J. Iguaz scite author profile

The direct detection of dark matter particles requires ultra-low background conditions at energies below a few tens of keV. Radioactive isotopes are produced via cosmogenic activation in detectors and other materials and those isotopes constitute a background source which has to be under control. In particular, tritium is specially relevant due to its decay properties (very low endpoint energy and long half-life) when induced in the detector medium, and because it can be generated in any material as a spallation product. Quantification of cosmogenic production of tritium is not straightforward, neither experimentally nor by calculations. In this work, a method for the calculation of production rates at sea level has been developed and applied to some of the materials typically used as targets in dark matter detectors (germanium, sodium iodide, argon and neon); it is based on a selected description of tritium production cross sections over the entire energy range of cosmic nucleons. Results have been compared to available data in the literature, either based on other calculations or from measurements. The obtained tritium production rates, ranging from a few tens to a few hundreds of nuclei per kg and per day at sea level, point to a significant contribution to the background in dark matter experiments, requiring the application of specific protocols for target material purification, material storing underground and limiting the time the detector is on surface during the building process in order to minimize the exposure to the most dangerous cosmic ray components.Comment: Final version as publishe

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The BiPo-3 detector for the measurement of ultra low natural radioactivities of thin materials

Barabash

Basharina-Freshville

Birdsall

et al. 2017

J. Inst.

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since 2013, is a low-radioactivity detector dedicated to measuring ultra low natural radionuclide contaminations of 208 Tl ( 232 Th chain) and 214 Bi ( 238 U chain) in thin materials. The total sensitive surface area of the detector is 3.6 m 2 . The detector has been developed to measure the radiopurity of the selenium double β-decay source foils of the SuperNEMO experiment. In this paper the design and performance of the detector, and results of the background measurements in 208 Tl and 214 Bi, are presented, and the validation of the BiPo-3 measurement with a calibrated aluminium foil is discussed. Results of the 208 Tl and 214 Bi activity measurements of the first enriched 82 Se foils of the double β-decay SuperNEMO experiment are reported. The sensitivity of the BiPo-3 detector for the measurement of the SuperNEMO 82 Se foils is A( 208 Tl) < 2 µBq/kg (90% C.L.) and A( 214 Bi) < 140 µBq/kg (90% C.L.

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New Developments in Micromegas Microbulk Detectors

et al. 2012

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A new Micromegas manufacturing technique, based on kapton etching technology, has been recently developed, improving the uniformity and stability of this kind of readouts. Excellent energy resolutions have been obtained, reaching 11% FWHM for the 5.9 keV photon peak of 55 Fe source and 1.8% FWHM for the 5.5 MeV alpha peak of the 241 Am source. The new detector has other advantages like its flexible structure, low material and high radio-purity. The two actual approaches of this technique will be described and the features of these readouts in argon-isobutane mixtures will be presented. Moreover, the low material present in the amplification gap makes these detectors approximate the Rose and Korff model for the avalanche amplification, which will be discussed for the same type of mixtures. Finally, we will present several applications of the microbulk technique.

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F.J. Iguaz

Accurate γ and MeV-electron track reconstruction with an ultra-low diffusion Xenon/TMA TPC at 10 atm

Cosmogenic production of tritium in dark matter detectors

The BiPo-3 detector for the measurement of ultra low natural radioactivities of thin materials

New Developments in Micromegas Microbulk Detectors

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