Murthy’s Interpretation on Different Types of Scattering

Murthy’s Interpretation on Different Types of Scattering

All interactions in nature are field interactions.  Charged particles in nature, due to their very nature of charge, have an electric field around them. As they move in space the field around the charged particle changes. The change in the electric field results in magnetic field, as the magnetic field is a symbiotic and conjoined twin of the changing electric field, except that the electric field and the magnetic field change in orthogonal relationship with each other. When the electric charge moves along a path or locus, the electric charge field increases from zero from its front, which is the direction of its movement, to a peak and reduce to zero at its tail point. Being orthogonal to the electric field, the magnetic field is zero when and at the point of the peak of the electric field, and goes to a peak when and at the same point when the electric field has gone from peak to zero. It is a push – pull relationship between the electric and magnetic fields.

This relationship explanation is true not only to the moving electric charge, and also to the light transmission. However, the charges particle may move much slower than the speed of light. If and when a charged particle moved faster and faster approaching the speed of light and ultimately reach the limit, it would have transformed into light.

The electron in an atom, orbiting around the nucleus, can gain a quantum of energy as it interacts with a ray of light incident on it. This quantum of energy results in an increased momentum in the electron. With this increased quantum of energy, in its resulting increased momentum pushes it to the higher orbit or a higher state of energy. It is important to understand that the interaction between the electromagnetic form of light and the electron is a field interaction. In this particular case, the field interaction happens at the intra-atomic scale or inside the atom. The light and the electron “do not touch each other”.

The different forms of scattering are only a result of this basic and fundamental field interaction. The different scattering and effects of light matter interactions are all effects of the light – electron interaction. Based on what the electron is doing in an atom, molecule, in solid, liquid, gas and their combinations in the matter the light - electron field interactions vary, and especially the quantum of energy donated by the light to the electron vary. For example, in a molecule made up of multiple atoms, the energy bond between the atoms is created by a shared electron between them. The shared electron has field relationship with the multiple atoms’ nucleus and the other non-shared electrons. The field relationship of the shared electron in its extended combined multiple atom family results in this energy bond. The quantum of energy required to alter this bond relationship status quo depends on the different atomic and molecular configuration in the matter, be it a solid, liquid or gas; be it a multi-phase like a colloidal mixture; be it a chain of molecules like a polymeric chain; be it a crystal; be it a metal; be it a nanowire or nano dot. It also depends on the temperature and pressure. The various semicolon separated I have given in the preceding sentence are only few of many possibilities. When the appropriate quantum of energy is donated by the incident light to the electron in this example, not only the electron receives this specific quantum of energy, the increased energy may have effect not only on the electron, but also its extended family relationship with other electrons, nuclei, the different atoms in the molecule, and also other molecules in the multiple molecules chain bigger family; the response and the result of the original light – electron field interaction is not only by the electron, but the whole extended family or even the bigger family of multiple entangled molecules. Not only the electron is entangled with in its atom host, it is entangled with other atoms sharing this electron, and the extended entanglement with the molecule or bigger family of multiple molecules.

Depending on the actual details of the primary, secondary and tertiary entanglement, different effects were discovered by various scientists in the last two to three centuries. The list of effects is very long. Therefore, I am listing only few here in this document, but will extend this list in the next few days.

Importance of KRS Murthy’s Contribution

While many discoveries have been made for the interaction of light with matter in different forms, and respective discoveries interpreted by various other scientists, further test variations and resulting corollary discoveries presented, none of the scientists have provided a unified approach to the large list of discoveries, from the basics of field interactions and the basic and fundamental interactions between the electron and incident electromagnetic radiation, like light, and the full spectrum of electromagnetic radiation.

My interpretation is that in all of nature all scattering and related effects, in all forms of matter, including the multi-phase, arise from the basic and fundamental nature of field interactions between the fundamental and elementary particles in the nature.

1. Rayleigh Scattering
2. Raman Scattering
3. Mei Scattering
4. Tyndall Scattering
5. Brillouin Scattering
6. Dynamic and Static Scattering
7. Elastic and Inelastic Scattering