Dynamic Interactions in the Atmosphere
Gabriel Barceló
Advanced Dynamics S.A., Madrid, Spain.
 DOI: 10.4236/acs.2014.45073   PDF   HTML   XML   4,833 Downloads   5,958 Views   Citations

Abstract

Even today, with the great progress that has been made in the scientific, technological and computational fields, we are still stunned by the devastating effects brought about by atmospheric phenomena. This paper aims to propose new hypotheses in the field of dynamics to enhance our understanding of the behaviour of atmospheric disturbances caused by rotating winds. I believe that the criteria of classical dynamics that are applied to vortex systems in the atmosphere should be rigorously reviewed. I propose to establish new hypotheses in the field of dynamics, in order to better interpret rotation in nature. These hypotheses have been structured into a new theory that has been tested experimentally by both ourselves and third parties, with positive results. I propose to use the Theory of Dynamic Interactions (TDI) to interpret the behaviour of systems undergoing successive rotations around different axes—which we will refer to as non-coaxial rotations. I hold that this theory applies to air masses and groups of particles in suspension that are accelerated by rotations. Accordingly, it should be used to interpret the behaviour of tornadoes, cyclones and hurricanes. I believe that this proposal could enhance our understanding of these atmospheric phenomena and improve predictions about them.

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Barceló, G. (2014) Dynamic Interactions in the Atmosphere. Atmospheric and Climate Sciences, 4, 828-840. doi: 10.4236/acs.2014.45073.

Conflicts of Interest

The authors declare no conflicts of interest.

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