Abstract
The Iron Calorimeter (ICAL) detector at the proposed India-based Neutrino Observatory (INO) aims to detect atmospheric neutrinos and antineutrinos separately in the multi-GeV range of energies and over a wide range of baselines. By utilizing its charge identification capability, ICAL can efficiently distinguish μ− and μ+ events. Atmospheric neutrinos passing long distances through Earth can be detected at ICAL with good resolution in energy and direction, which enables ICAL to see the density-dependent matter oscillations experienced by upward-going neutrinos in the multi-GeV range of energies. In this work, we explore the possibility of utilizing neutrino oscillations in the presence of matter to extract information about the internal structure of Earth complementary to seismic studies. Using good directional resolution, ICAL would be able to observe 331 μ− and 146 μ+ core-passing events with 500 kt·yr exposure. With this exposure, we show for the first time that the presence of Earth’s core can be independently confirmed at ICAL with a median ∆χ2 of 7.45 (4.83) assuming normal (inverted) mass ordering by ruling out the simple two-layered mantle-crust profile in theory while generating the prospective data with the PREM profile. We observe that in the absence of charge identification capability of ICAL, this sensitivity deteriorates significantly to 3.76 (1.59) for normal (inverted) mass ordering.
Highlights
The neutrinos have the potential to throw some light on the internal structure of Earth via neutrino absorption, oscillations, and diffraction
Atmospheric neutrinos passing long distances through Earth can be detected at Iron Calorimeter (ICAL) with good resolution in energy and direction, which enables ICAL to see the density-dependent matter oscillations experienced by upward-going neutrinos in the multi-GeV range of energies
Matter effect is experienced by upward-going neutrinos only, we have considered cos θμrec in the range of -1 to 1 because downward-going events help in increasing overall statistics as well as minimizing normalization uncertainties in atmospheric neutrino events
Summary
The neutrinos have the potential to throw some light on the internal structure of Earth via neutrino absorption, oscillations, and diffraction. A neutrino detector with good resolution in the multi-GeV range of energy and direction of neutrino will be able to observe modified event distribution due to neutrino oscillations in the presence of matter. The good directional resolution at ICAL is used to identify neutrinos passing through core, mantle, and crust in section 5 which describes the resultant distribution of reconstructed muon events for these neutrinos passing through a particular set of layers. The seismic studies have revealed that Earth consists of concentric shells, which are crust, mantle, and core, each of them is further divided into subshells with different properties [53, 55, 56]. The radius of the core is almost half the radius of Earth, whereas the density of the core is twice that of the mantle
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