The Duality of Time Theory, that results from the Single Monad Model of the Cosmos, explains how physical multiplicity is emerging from absolute (metaphysical) Oneness, at every instance of our normal time! This leads to the Ultimate Symmetry of space and its dynamic formation and breaking into the physical and psychical (supersymmetrical) creations, in orthogonal time directions. General Relativity and Quantum Mechanics are complementary consequences of the Duality of Time Theory, and all the fundamental interactions become properties of the new granular complex-time geometry, at diifferent dimensions. - => Conference Talk [Detailed Presentation]
... al and psychical worlds are the pairs of super symmetry, which is the symmetry between particles and anti-particles, both together as fermions mirror the four bosons, according to the hyper symmetry group. This symmetry is generated by the same mass-energy equivalence ( E=mc 2 ), which we ...
... al and psychical worlds are the pairs of super symmetry, which is the symmetry between particles and anti-particles, both together as fermions mirror the four bosons, according to the hyper symmetry group. This symmetry is generated by the same mass-energy equivalence (), which we showed i ...
... t for manifolds of different topologies. For example, for the Schwarzschild metric, the corresponding Killing group is a subgroup of the Poincar group. Nevertheless, if one searches for the symmetry group that leaves a general metric of the Einstein equation invariant one finds that this g ...
... y defines the Standard Model. Roughly, the three factors of the gauge symmetry give rise to the three fundamental interactions. The fields fall into different representations of the various symmetry groups of the Standard Model: , and . Upon writing the most general Lagrangian, one f ...
... y defines the Standard Model. Roughly, the three factors of the gauge symmetry give rise to the three fundamental interactions. The fields fall into different representations of the various symmetry groups of the Standard Model: , and . Upon writing the most general Lagrangian, one finds t ...
... the latter are redundancies in our description of the physical system, so they are not real. In global symmetries, the quantum eigen-states can be divide in terms of representations of the symmetry group, and the physical operators go between different states. In contrast, in local symmet ...
... oc techniques. Group representations help understanding their properties by studying how do they act on different spaces, so they are very important in physics because they describe how the symmetry group of a physical system affects the solutions of equations describing that system.   ...
... of time are orthogonal. Pierre Curie was the first to study the role of symmetry breaking in his famous 1894 article, in which he explains symmetry breaking as the lowering of the original symmetry group of the medium to the sub-group of the phenomenon, by the action of some cause [[10]]. ...
... many other properties of the system. For example, the speed of light has the same value in all frames of reference, so this forms a symmetry that is described by Poincar group, which is the symmetry group of Special Relativity. Symmetry can also be observed with respect to the passage of t ...
... ormations of the space-time coordinates that project the laws of electrodynamics from any observer s reference frame to any other inertial frame, such that the laws remain unchanged, is the symmetry group called after Poincar group. As we shall discuss further in section III.1.1, the theor ...
... ternal symmetries and the Coleman Mandula theorem showed that under certain assumptions, the symmetries of the S-matrix must be a direct product of the Poincar group with a compact internal symmetry group, or if there is no mass gap, the conformal group with a compact internal symmetry gro ...
... ame symmetry. When the system goes to one of those vacuum solutions, the symmetry is broken for perturbations around that vacuum even though the entire Lagrangian retains that symmetry. The symmetry group can be discrete or continuous, but if the system contains only a single spatial dimen ...
... its faces. For each of the regular polyhedra, these three spheres are concentric. The radii of the spheres are called the circum-radius, the mid-radius, and the in-radius respectively. The symmetry groups of the regular polyhedra are a special class of three-dimensional point groups known ...
... its faces. For each of the regular polyhedra, these three spheres are concentric. The radii of the spheres are called the circum-radius, the mid-radius, and the in-radius respectively. The symmetry groups of the regular polyhedra are a special class of three-dimensional point groups known ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... t is so different from the other polyhedra, in virtue of its pentagonal faces. Timaeus contains a very detailed discussion of virtually all aspects of physical existence, including biology, cosmology, geography, chemistry, physics, psychological perceptions, all expressed in terms of these ...
... roups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
... geometric solids whose faces are regular and identical polygons meeting at equal three-dimensional angles. These five regular polyhedra are the only solid shapes with this sort of complete symmetry. Many philosophers wondered why there cannot be more, or fewer, so perfectly symmetrical sh ...
... mmetry groups are twice as much again (24, 48, and 120). All regular polyhedra except the Tetrahedron are centrally symmetric, meaning they are preserved under reflection through the origin. ...
I have no doubt that this is the most significant discovery in the history of mathematics, physics and philosophy, ever!
By revealing the mystery of the connection between discreteness and contintuity, this novel understanding of the complex (time-time) geometry, will cause a paradigm shift in our knowledge of the fundamental nature of the cosmos and its corporeal and incorporeal structures.
Enjoy reading...
Mohamed Haj Yousef
Check this detailed video presentation on "Deriving the Principles of Special, General and Quantum Relativity Based on the Single Monad Model Cosmos and Duality of Time Theory".
Download the Book "DOT: The Duality of Time Postulate and Its Consequences on General Relativity and Quantum Mechanics" or: READ ONLINE .....>>>>