Yarman, Nuh TolgaYarman, T.Arik, M.Kholmetskii, A. L.Enerji Sistemleri Mühendisliği / Energy Systems Engineering2024-10-152024-10-15201132146-1147[WOS-DOI-BELIRLENECEK-265]https://hdl.handle.net/20.500.14517/6499Yarman, Tolga/0000-0003-3209-2264t. We base the present approach, on an alternative theory of gravitation, consisting essentially on the law of energy conservation broadened to embody the mass & energy equivalence of the Special Theory of Relativity, and remedying, known problems and incompatibilities, associated with the actually reigning conception. The mere rotation problem of say, a sphere, can well be undertaken, along the same idea. Accordingly, we consider the problem of gravity created by a rotating celestial body. Finally we apply our results to the case of a geosynchronous satellite, which is, schematically speaking, nothing but a clock placed on a considerably high tower. The approach ironically furnishes the Newtons law of motion, which however we derive, based on just static forces, and not an acceleration, governing a motion. (There is anyway no motion for a geosynchronous satellite, when observed from Earth.) We predict accordingly that, the blue shift of light from a geosynchronous satellite on an orbit of radius rGs should be softened as much as (omega(2)/2c(2)) (r(Gs)(2) - R-2) as compared to what is expected classically; here omega Earths self rotation angular momentum, R Earths radius, and c the speed of light in empty space. We hope, the validity of this unforeseen prediction, can soon be checked out.eninfo:eu-repo/semantics/closedAccessGeosynchronous satellitesblue shiftred shiftgeneral theory of relativityCorrected Kndig EffectArticleQ411109125WOS:000218991100011