As studied, atoms deal with the positive or negative charge by losing or
gaining an electron. However, the gaseous and solid atoms can execute
interstate electron dynamics. They can also deal with transition states. Solid
atoms can elongate from the east-west poles at the ground surface level. Under
suitable energy, solid atoms can expand, and gaseous atoms can contract. When
the excessive field is intact, flowing inert gas atoms can split. The splitting
inert gas atoms convert into electron streams. Those electron streams carrying
the photons when impinging on the naturally-elongated solid atoms, further
elongation of the atoms takes place. If not, elongated atoms at least deform.
Gaseous atoms can squeeze by the suffering of their lattices. Such behaviors of
the atoms validate that they cannot ionize. On splitting the flowing inert gas
atoms, characteristics of the photons become apparent. Those photons that are
not carried by the electron streams can enter the air medium directly. On
traveling photons in the air medium, their energy dissipates in heat, and their
force confines in the form of a field. On confinement of the field of traveling
photons with the field of air-medium, a glow of light is appeared, which is
better known in plasma. The splitting of inert gas atoms, the carrying of
photons by the electron streams, and the lighting of traveling photons validate
that an electric current is photonic. In various microscopes, the magnification
of an image is based on the resolving power of photons. Photonic current is due
to the propagation of the photons in the structure of the interstate electron
gap. Some well-known principles are also discussed, validating that an electric
current is a photonic current. Indeed, this study brings about profound changes
in science