Abstract
A theory employing the vortex shape of the electron was presented to resolve the enigma of the wave-particle duality. Conventions such as “particle” and “wave” were used to describe the behavior of quantum objects such as electrons. A superfluid vacuum formed the base to describe the basic vortex structure and properties of the electron, whereas various formulations derived from hydrodynamic laws described the electron vortex circumference, radius, angular velocity and angular frequency, angular momentum (spin) and magnetic momentum. A vortex electron fully explained the associations between momentum and wave, and hydrodynamic laws were essential in deriving the energy and angular frequency of the electron. In general, an electron traveling in space possesses internal and external motions. To derive the angular frequency of its internal motion, the Compton wavelength was used to represent the length of one cycle of the internal motion that is equal to the circumference of the electron vortex. The angular frequency of the electron vortex was calculated to obtain the same value according to Planck’s theory. A traveling vortex electron has internal and external motions that create a three-dimensional helix trajectory. The magnitude of the instantaneous velocity of the electron is the resultant of its internal and external velocities, being equal to the internal velocity reduced by the Lorentz factor (whose essence is presented in a detailed formulation). The wavelength of the helix trajectory represents the distance traveled by a particle along its axis during one period of revolution around the axis, resulting in the same de Broglie wavelength that corresponds to the helix pitch of the helix. Mathematical formulations were presented to demonstrate the relation between the energy of the vortex and its angular frequency and de Broglie’s wavelength; furthermore, Compton’s and de Broglie’s wavelengths were also differentiated.
Highlights
Wave-particle duality is one of the fundamental principles of quantum mechanics which is directly linked to many of its mysteries
The magnitude of the instantaneous velocity of the electron is the resultant of its internal and external velocities, being equal to the internal velocity reduced by the Lorentz factor
Hydrodynamic laws are applied to study the behavior of such a vortex which has internal rotation, angular momentum, angular speed, and angular frequency
Summary
Wave-particle duality is one of the fundamental principles of quantum mechanics which is directly linked to many of its mysteries According to this theory, light and matter exhibit properties of both waves and particles. N. Butto showed that light, considered a form of electromagnetic waves, must be thought of as particle-like, localized in packets of discrete energy. Considered a form of electromagnetic waves, must be thought of as particle-like, localized in packets of discrete energy In his theory of photoelectric effect, he posited that when light is shown on certain objects, electrons will be released; if a photon of an energy greater than that of the electron hits a solid, that electron will be emitted. The local physical reality of the electron as a vortex determines the results of local measurements
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