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The direction of 3D time seems most evident because it corresponds to our usual way of thinking. There are two time arrows: from the past to the future and vice versa, as described in the section on antimatter. On the other hand, with regard to the present — which basically means connecting different densities by means of vibratory harmonics*— I think entanglement or quantum correlation may be a neverending source of wonder. Entanglement has been the object of many scientific articles, particularly after the experiment of Geneva conducted in 2002 when some journalists wrote that time stopped. The objective of this experiment was to take the next step in the study of entanglement, which I will discuss later on. This experiment showed the interference of two photons leaving in different directions, even opposite ones. lam arguing that the properties of two particles are complemen- tary, whether or not the spin of one of them is altered, for a simple rea- son that I have never seen iterated explicitly by any scientist before: it is the same particle! In addition, this can be true only if the experiment is interpreted based on, among others, the concept of 3D time. There is absolutely no need to apply any hidden variables, local or otherwise, that have divided physicists so much. Unless the non-local hidden variable is 3D time. When we see two photons, there is actually only one! The separation occurs because we see things from the viewpoint of another ST, the laboratory. We should keep in mind that time multi- plies while space progressively disappears. In fact, these photons respond to the wave function (probabilistic function) that enables par- ticles to be potentially in several different places (hence quantum deco- herence). In the case of the entanglement experiment, the pair of photons was obtained by going through a present coordinate very dis- tant from ours, i.e., in a quasi-absolute instantaneity for a single local- ized harmonic. This ability to isolate (interference suppression) one of many parameters of quantum mechanics experiments (motions in particular) allows us to control such very high frequency harmonics. The super- natural i is the mere occurrence of conditions that favor higher quanti- e4 : m a a a 1 oo ties of harmonics. The more there are, the rarer the phenomenon will be. A harmonic is indeed an integral multiple of a frequency. The greater their number, the greater the sensitivity required. The ETs have actually achieved such control in UFOs. The difficulty lies in the align- ment with infinitely small and extremely specific frequencies, equaling high temporal densities and thus the fractal distancing of our ST. Understanding the above is so important that we need to take it one eon step further.