The fourth dimension is real, scientifically proven

The discovery of the fourth dimension challenges ideas about the nature of matter.

A group of scientists discovered that electrons move in the fourth dimension. With their ultra-fast speeds, these electrons seem to challenge our understanding of the universe. Since high school we have been taught all about atomic models, especially electrons, and since then we have been told that they are on a three-dimensional journey.

After recent research, it was discovered that electrons do not operate in the third dimension but in the so-called energy dimension. A space where time and energy merge in a unique way.

These electrons are called Dirac electrons because to fully understand their properties, they must be described in four-dimensional space.

An important milestone in physics: electrons move in the fourth dimension

A team of physicists led by Dr. Ryuhei Oka of Ehime University in Japan has made an unprecedented breakthrough by observing electrons moving at extremely fast speeds in four-dimensional space.

The researchers focused on a special material called bis(ethylenedithio)-tetrathiafulvalene, a superconducting polymer. What they discovered was actually something never seen before: Dirac electrons, particles that are characterized by their lack of mass, allowing them to reach incredible speeds.

In addition to moving through the three dimensions of space we know, these electrons also move through what experts call the energy dimension: a space where time and energy are intertwined in a completely new way.

The Fourth Dimension is a project with many challenges

We know that the behavior of electrons in materials is determined by certain quantum properties that determine their orbits in the substance of which they are part.

This phenomenon is similar to the way light traveling through the universe is altered by the presence of stars, black holes, dark matter or dark energy, which can warp the space-time continuum.

Although Dirac electrons are closely related to topological materials, studying these electrons is not an easy task. Their coexistence with ordinary electrons means that their detection and measurement remains a scientific challenge.

Well, to overcome this obstacle, scientists used an innovative technique called electron spin resonance. This method allowed them to observe how electrons interact with magnetic fields, using the spin charge distribution of electrons to distinguish them from their standard counterparts.

They discovered that the speed of these electrons is not constant but varies depending on factors such as temperature and the angle of the magnetic field.

Therefore, the existence of Dirac electrons moving in the fourth dimension forces us to rethink the laws that govern the subatomic world. This opens the door to new technologies. that will allow the development of ultrafast electronics, next-generation quantum computers and even materials with properties that we do not yet know.

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