Geoneutrinos and geoscience: an intriguing joint-venture

Bellini, G.; Inoue, K.; Mantovani, Fabio; Serafini, Andrea; Strati, Virginia; Watanabe, Hiroko

doi:10.1007/s40766-021-00026-7

Cited by 7 publications

(3 citation statements)

References 180 publications

(350 reference statements)

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“…If we talk about the presence of light elements inside Earth, we don't know how much H 2 O is present in the mantle and how much H is present in the core [15,20,21]. The precise measurement of radioactive power produced in the mantle and core is important to understand the thermal dynamics inside Earth [22][23][24][25].…”

Section: Jhep04(2023)068mentioning

confidence: 99%

Locating the core-mantle boundary using oscillations of atmospheric neutrinos

Upadhyay

Kumar

Agarwalla

et al. 2023

J. High Energ. Phys.

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Atmospheric neutrinos provide a unique avenue to explore the internal structure of Earth based on weak interactions, which is complementary to seismic studies and gravitational measurements. In this work, we demonstrate that the atmospheric neutrino oscillations in the presence of Earth matter can serve as an important tool to locate the core-mantle boundary (CMB). An atmospheric neutrino detector like the proposed 50 kt magnetized ICAL at INO can observe the core-passing neutrinos efficiently. These neutrinos would have experienced the MSW resonance and the parametric or neutrino oscillation length resonance. The net effect of these resonances on neutrino flavor conversions depends upon the location of CMB and the density jump at that radius. We quantify the capability of ICAL to measure the location of CMB in the context of multiple three-layered models of Earth. For the model where the density and the radius of core are kept flexible while the mass and radius of Earth as well as the densities of outer and inner mantle are fixed, ICAL can determine the location of CMB with a 1σ precision of about 250 km with an exposure of 1000 kt yr. With the 81-layered PREM profile, this 1σ precision would be about 350 km. The charge identification capability of ICAL plays an important role in achieving this precision.

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Section: Jhep04(2023)068mentioning

confidence: 99%

Locating the core-mantle boundary using oscillations of atmospheric neutrinos

Upadhyay

Kumar

Agarwalla

et al. 2023

J. High Energ. Phys.

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“…However, this is not the case. The exiguous tidal dissipation (≈0.1 TW) and gravitational potential energy released in the differentiation of crust from mantle (≈0.2 TW) can be neglected [85]. The geodynamic approach with its hypothesis of convective currents in the mantle would imply a faster dissipation of primordial heat, estimating values below the average of ≈10 TW.…”

Section: The Earth's Heat Flux Budget Is Not Balancedmentioning

confidence: 99%

“…Furthermore, it is important to consider that the feedback from an Expanding Earth on primeval heat evaluation would lead to a primitive heat re-evaluation much lower than 5 -15 TW, making the lack of a plausible heat source more dramatic. This serious question of the Earth's actual evolution skews all estimates of the Earth's primordial heat, without the authors being aware since they are mainly interested in balancing the Earth's heat budget within the framework of current knowledge, in which the expansion of celestial bodies is not considered [83] [84] [85]. The budget can only be balanced by arguing the existence of an unidentified source of heat possibly linked to the unknown physical phenomenon that drives terrestrial expansion.…”

Section: The Earth's Heat Flux Budget Is Not Balancedmentioning

confidence: 99%

A Non-Newtonian View of the Universe Derived from Hydrodynamic Gravitation and Expanding Earth

Scalera¹

2022

JMP

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Earth Science observations and the Borexino and KamLAND geoneutrino experiments provide clues on the role of aether in the evolution of the Earth, planets, and all other universal structures. Analysis of the problem of storage of aether entering celestial bodies led to a hydrodynamic explanation of gravitation which in turn was found to be closely related to the expanding Earth and to several other phenomena. Variable radius paleogeography provides an approximate assessment of the quantity of ordinary matter added to the planet per time unit, and some inferences about the Earth's inner energy balance. The aether density, flow rate, and velocity are computed with the help of astrophysics. The origins of cosmological and gravitational redshift are unified under the single cause of gravitation. This is linked to the similar but not interchangeable concept of tired light, which was considered very plausible by cosmologists like Edwin Hubble and Fritz Zwicky. A superluminal speed was calculated for aether at the Earth's surface. INFN experiments confirm hydrodynamic gravitation and superluminal velocities, and it is possible to identify interrelations of aether parameters with the currently known cosmological parameters H 0 , G, and c. Unification of hydrodynamic gravitation and the expansion of the celestial bodies through the existence of a minor dissipative force, a non-Newtonian concept, involves a revision of the theories of physics and cosmology, in which the currently accepted laws of physics will be only considered good approximations of a more complex reality.

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Quantifying Earth's radiogenic heat budget

Sammon

McDonough

2022

Preprint

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Geoneutrinos and geoscience: an intriguing joint-venture

Cited by 7 publications

References 180 publications

Locating the core-mantle boundary using oscillations of atmospheric neutrinos

Locating the core-mantle boundary using oscillations of atmospheric neutrinos

A Non-Newtonian View of the Universe Derived from Hydrodynamic Gravitation and Expanding Earth

Quantifying Earth's radiogenic heat budget

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