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1. Reconstructing the neutrino energy for in-ice radio detectors: A study for the Radio Neutrino Observatory Greenland (RNO-G)

   https://doi.org/10.1140/epjc/s10052-022-10034-4  

   Aguilar, J. A.; Allison, P.; Beatty, J. J.; Bernhoff, H.; Besson, D.; Bingefors, N.; Botner, O.; Bouma, S.; Buitink, S.; Carter, K.; et al (February 2022, The European Physical Journal C)

   Abstract Since summer 2021, the Radio Neutrino Observatory in Greenland (RNO-G) is searching for astrophysical neutrinos at energies$${>10}$$ $>10$ PeV by detecting the radio emission from particle showers in the ice around Summit Station, Greenland. We present an extensive simulation study that shows how RNO-G will be able to measure the energy of such particle cascades, which will in turn be used to estimate the energy of the incoming neutrino that caused them. The location of the neutrino interaction is determined using the differences in arrival times between channels and the electric field of the radio signal is reconstructed using a novel approach based on Information Field Theory. Based on these properties, the shower energy can be estimated. We show that this method can achieve an uncertainty of 13% on the logarithm of the shower energy after modest quality cuts and estimate how this can constrain the energy of the neutrino. The method presented in this paper is applicable to all similar radio neutrino detectors, such as the proposed radio array of IceCube-Gen2. 

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2. Multi-calorimetry in light-based neutrino detectors

   https://doi.org/10.1007/JHEP12(2024)002  

   Cabrera, Anatael; Han, Yang; Calvez, Steven; Chauveau, Emmanuel; Chen, Hanyi; de_Kerret, Hervé; Dusini, Stefano; Grassi, Marco; Imbert, Leonard; Li, Jiajun; et al (December 2024, Journal of High Energy Physics)

   A<sc>bstract</sc> Neutrino detectors are among the largest photon detection instruments, built to capture scarce photons upon energy deposition. Many discoveries in neutrino physics, including the neutrino itself, are inseparable from the advances in photon detection technology, particularly in photo-sensors and readout electronics, to yield ever higher precision and richer detection information. The measurement of the energy of neutrinos, referred to ascalorimetry, can be achieved in two distinct approaches: photon-counting, where single-photon can be counted digitally, and photon-integration, where multi-photons are aggregated and estimated via analogue signals. The energy is pursued today to reach permille level systematics control precision in ever-vast volumes, exemplified by experiments like JUNO. The unprecedented precision brings to the foreground the systematics due to calorimetric response entanglements in energy, position and time that were negligible in the past, thus driving further innovation in calorimetry. This publication describes a novel articulation that detectors can be endowed with multiple photon detection systems. Thismulti-calorimetryapproach opens the notion ofdual-calorimetrydetector, consisting of both photon-counting and photon-integration systems, as a cost-effective evolution from thesingle-calorimetrysetups used over several decades for most experiments so far. The dual-calorimetry design exploits unique response synergies between photon-counting and photon-integration systems, including correlations and cancellations in calorimetric responses, to maximise the mitigation of response entanglements, thereby yielding permille-level high-precision calorimetry. 

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3. Dark Matter Annihilation inside Large-Volume Neutrino Detectors

   https://doi.org/10.1103/PhysRevLett.131.011005  

   McKeen, David; Morrissey, David E.; Pospelov, Maxim; Ramani, Harikrishnan; Ray, Anupam (July 2023, Physical Review Letters)
4. Muon Energy Reconstruction for Neutrino Detectors with Edepillim

   https://doi.org/10.22323/1.358.0909  

   Hill, Gary; Robertson, Sally (July 2021, PoS ICRC2019)

   null (Ed.)
5. Low-energy solar neutrino detection utilizing advanced germanium detectors

   https://doi.org/10.1088/1361-6471/acc751  

   Bhattarai, S; Mei, D-M; Raut, M S (April 2023, Journal of Physics G: Nuclear and Particle Physics)

   Abstract We explore the possibility to use advanced germanium (Ge) detectors as a low-energy solar neutrino observatory by means of neutrino-nucleus elastic scattering. A Ge detector utilizing internal charge amplification for the charge carriers created by the ionization of impurities is a novel technology with experimental sensitivity for detecting low-energy solar neutrinos. Ge internal charge amplification (GeICA) detectors will amplify the charge carriers induced by neutrino interacting with Ge atoms through the emission of phonons. It is those phonons that will create charge carriers through the ionization of impurities to achieve an extremely low energy threshold of ∼0.01 eV. We demonstrate the phonon absorption, excitation, and ionization probability of impurities in a Ge detector with impurity levels of 3 × 10 10 cm −3 , 9 × 10 10 cm −3 , and 2 × 10 11 cm −3 . We present the sensitivity of such a Ge experiment for detecting solar neutrinos in the low-energy region. We show that, if GeICA technology becomes available, then a new opportunity arises to observe pp and 7 Be solar neutrinos. Such a novel detector with only 1 kg of high-purity Ge will give ∼10 events per year for pp neutrinos and ∼5 events per year for 7 Be neutrinos with a detection energy threshold of 0.01 eV. 

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