We are electromagnetic fields

The hydrogen atom is composed of charged particles that move relative to each other. Although the relative movement of nuclear mass and electrons is very small compared to the amplitude of the electron’s motion on a large spherical surface, this movement generated by charges creates an electromagnetic field in the space between the nucleus and the electron. In other words, the movement of charged particles determines an electromagnetic field that extends beyond the atomic shell and can interact with other hydrogen atoms or different atoms.

Interactions between atoms of the same type or with other atoms lead to the formation of monoatomic or polyatomic molecules. These molecules generate their own electromagnetic field that manifests itself in the surrounding environment in a specific way. This feature is important because it means that increasingly complex molecules can form through the interaction of their electromagnetic fields.

Interestingly, all molecules, from the simplest to those that make up plant and animal life, can be described by a wave function determined by the continuous movement of electrons in atoms and molecules. These interactions of electromagnetic fields also represent the medium through which matter perceives the presence of other molecules.

A tangible example of these interactions is digital electronics, which use electromagnetic fields to encode and transport information remotely. It is interesting to imagine potential future developments, such as the teleportation of electromagnetic information for the duplication of masses or organisms, even if at the moment it remains science fiction.

In conclusion, plant and animal life can be described based on the electromagnetic fields generated by the molecules that make up matter. We are made up of constantly changing matter and electromagnetic fields, and many of our characteristics, such as the food we consume, the drugs we take, and our ability to communicate, may depend on the electromagnetic properties of the molecules that compose us.