Relativistic Non-local Physics in the Theory of Gravitational Field Interaction with a Laser Beam
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Boris V. Alexeev, Physics Department, Moscow Lomonosov State University of Fine Chemical Technologies, Prospekt Vernadskogo, Moscow, Russia.
Relativistic non-local physics is applied to the problem of a laser beam interaction with gravitational field including gravitational waves. We intend to answer the following questions: a) Is it possible to speak about interaction of a laser beam (for example) with gravitational field? b) Can we admit the existence of gravitational waves from position of non-local relativistic physics? It is shown that both questions have the positive answers. In other words - the non-local treatment does not lead to the mathematical contradictions in the theory. It is shown that the problem of gravitational field interaction with a laser beam cannot be solved in the frame of local theoretical physics in principal. An analog of Newton' law for the photon movement is obtained. Many concrete results of calculations are delivered.
Relativistic Non-local Physics, Newton' Law for the Photon Movement , Gravitational Field, Laser Beam Interaction
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