Kelvin Waves and Dynamic Knots on Vortex-Membrane

Abstract

Quantum mechanics is a successful theory that describes the behavior of photons, electrons, and other atomic- and molecular-scale objects. However, it is far from being well understood. In this paper, a new theory - knot physics for entangled vortex-membranes is developed to explore the underline physics of quantum mechanics. From point view of information, three dimensional quantum Dirac model is developed to effectively describe the fluctuations of local deformation of vortex-membranes: The elementary excitations are knots with information unit; The physics quality to describe local deformation is knot density that is defined by the density of zeros between two projected vortex-membranes; The Biot-Savart equation for Kelvin waves becomes Schrodinger equation for probability waves of knots; the classical functions for perturbative Kelvin waves become wave functions for knots; The probability of quantum mechanics comes from dynamic projection for inner observers owing to "fast clock" effect; The angular frequency for leapfrogging motion plays the role of the mass of knots; etc. This work would help people to understand the mystery of quantum mechanics.