Earth tomography with oscillating neutrinos at ICAL

Published in Springer Proc. Phys., 2024

Recommended citation: Anuj Kumar Upadhyay, Anil Kumar, Sanjib Kumar Agarwalla, Amol Dighe "Earth tomography with oscillating neutrinos at ICAL", Proceedings of the XXV DAE-BRNS High Energy Physics (HEP) Symposium 2022, IISER, Mohali, India, 12-16 Dec, 2022. Springer Proc. Phys. 304 (2024) 294-297. https://doi.org/10.1007/978-981-97-0289-3_64

Conference: The XXV DAE-BRNS High Energy Physics (HEP) Symposium 2022, IISER, Mohali, India, 12-16 Dec, 2022.

Abstract: The information about Earth’s internal structure comes from indirect probes such as seismic studies and gravitational measurements. The density distribution inside Earth, incorporated in the Preliminary Reference Earth Model (PREM), is estimated from the model-dependent empirical relations having assumptions based on Earth’s temperature, pressure, composition, and elastic properties, which give rise to uncertainties in the PREM profile. Atmospheric neutrinos using weak interactions provide a unique avenue to explore Earth’s internal structure, which are complementary to seismic studies and gravitational measurements based on electromagnetic and gravitational interactions, respectively. These complementary approaches would pave the way for “multi-messenger tomography of Earth”. Atmospheric neutrinos offer the possibility of validating the Earth’s core, measuring the location of the Core-Mantle Boundary (CMB), and probing dark matter (DM) inside the core in a unique way through Earth matter effects in neutrino oscillations. We explore these possibilities using a proposed Iron Calorimeter (ICAL) detector at the India-based Neutrino Observatory (INO). With 500 kt$\cdot$yr exposure, we show that the presence of Earth’s core can be independently confirmed at ICAL with a median $\Delta\chi^2$ of 7.45 (4.83), assuming normal (inverted) mass ordering. We demonstrate that the ICAL detector with 1000 kt$\cdot$yr exposure would be able to locate the CMB with a precision of about $\pm 250$ km at $1\sigma$ confidence level. It would also be sensitive to the possible presence of DM with 3.5% of the mass of Earth at the $1\sigma$ confidence level. We find that for all these Earth’s matter-driven measurements, the charge identification capability (CID) of the ICAL detector is crucial.

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