Research Article

How to Interpret Gravitational Events in the Newton´s Rotating Bucket? (Gravitational Phonons)

Jiří Stávek
Independent researcher, Czech Republic
* Corresponding author
DOI icon 10.24018/ejphysics.2022.4.2.159

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Submitted 2022-02-09
Published 2022-03-04

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The Newton´s rotating bucket with gravitational events occurring in that bucket is a starting point for any new model describing gravitational situations and serves as a “filter” for any proposed gravitational model. The topic of this contribution is to describe the self-organization of H2O molecules in the rotating bucket based on the Einstein-Shannon (ES) log-normal distribution of gravitationally redshifted velocities of H2O molecules. The joint co-operation of the Earth´s gravitational field with the centrifugal force acts as that “hidden” organizing agent. H2O molecules transfer the gravitational phonons and reflect them on the surfaces of the wall, bottom, and the water surface of Newton´s bucket and form the 3D paraboloid. Five new experimental predictions are proposed and compared with the experiments. The external observer is unaware that the H2O molecules in Newton´s bucket are phonon velocity-organized due to the Earth´s gravitational redshift and the rotation of Newton´s bucket. The microscopic interplay of gravitational phonons inside of Newton´s bucket is hidden from the macroscopic analysis of the external observers. The external observer claims that these centrifugal forces are fictitious. In order to discover the real actions of those self-organized forces, the observer has to be a part of the rotating system in the presence of the Earth´s gravitational field or to study the rotating system in proposed experiments.  

Keywords: Newton´s rotating bucket, ES log-normal distribution, phonon velocity-organization of molecules, gravitational phonons, properties of the paraboloid

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