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arxiv: 2110.13033 · v3 · pith:QNEJ2EBK · submitted 2021-10-25 · hep-ex · physics.ins-det

Search for coherent elastic neutrino-nucleus scattering at a nuclear reactor with CONNIE 2019 data

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classification hep-ex physics.ins-det
keywords coherentdatareactorccdsconnieelasticexperimentinteraction
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The Coherent Neutrino-Nucleus Interaction Experiment (CONNIE) is taking data at the Angra 2 nuclear reactor with the aim of detecting the coherent elastic scattering of reactor antineutrinos with silicon nuclei using charge-coupled devices (CCDs). In 2019 the experiment operated with a hardware binning applied to the readout stage, leading to lower levels of readout noise and improving the detection threshold down to 50 eV. The results of the analysis of 2019 data are reported here, corresponding to the detector array of 8 CCDs with a fiducial mass of 36.2 g and a total exposure of 2.2 kg-days. The difference between the reactor-on and reactor-off spectra shows no excess at low energies and yields upper limits at 95% confidence level for the neutrino interaction rates. In the lowest-energy range, 50-180 eV, the expected limit stands at 34 (39) times the standard model prediction, while the observed limit is 66 (75) times the standard model prediction with Sarkis (Chavarria) quenching factors.

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  1. Searches for CE{\nu}NS and Physics beyond the Standard Model using Skipper-CCDs at CONNIE

    hep-ex 2024-03 unverdicted novelty 7.0

    CONNIE's first Skipper-CCD run at Angra-2 yields no CEνNS excess, comparable prior limits on neutrino rates, improved bounds on light vector mediators, and record surface DM-electron limits via diurnal modulation.