[论文解读] Atoms of electron transition deform or elongate but do not ionize while inert gas atoms split under photonic current instead of electric

In many studies, atoms deal with the positive or negative charges by losing or gaining their electrons, but atoms can execute interstate electron dynamics while dealing with a dedicated state. When gaseous or solid atoms undertake different transition states, electrons can deal with infinitesimal displacements by remaining within their occupied energy knots. Such possibilities show that atoms cannot ionize, but the inert gas atoms can split into the electron streams. A generated field of the propagating photons can distort the flowing inert gas atoms. On splitting inert gas atoms, electrons carry forcing energy of the chasing photons. Moreover, solid atoms deform or elongate when travelling electrons impinge on them. Gaseous atoms also undertake squeezing, where the contraction of energy knots takes place. Such behaviors of the atoms also indicate that they do not ionize. On splitting flowing inert gas atoms due to the current of photons, the characteristics of propagating photons become obvious. On propagating the photons in air medium, the element of heat energy dissipates while the element of force confines, so a glow of light known as plasma appears. The splitting of inert gas atoms into the electron streams, the carrying of photons by the electrons, and the lighting of travelling photons infer that electric current is a photonic current. A magnification of image is based on the resolving power of photons in microscopic analysis. A photonic current is due to the propagation of featured photons through interstate electron gap or photonic band gap. Some important principles are also discussed here, which infer the photonic current. Indeed, the study brings about vast changes in the existing state of science and technology.