How Are Mass, Space Size, And Period of Time Structured, In Diatomic Molecules? Part II: Quantum Numbers of Electronic States: Difference between revisions

Scientific Paper
Title	How Are Mass, Space Size, And Period of Time Structured, In Diatomic Molecules? Part II: Quantum Numbers of Electronic States
Read in full	Link to paper
Author(s)	Tolga Yarman
Keywords	{{{keywords}}}
Published	2004
Journal	None

Latest revision as of 22:37, 1 January 2017

Read the full paper here

Abstract

In our previous article we arrived at an essential relationship for the classical vibration period of a diatomic molecule. It is that the cast of this relationship, [period of time] ~ [mass] x [size of space of concern]², is essentially imposed by the special theory of relativity; this is how we originally arrived to it, although we have derived it, quantum mechanically, in Part I of this work. The above relationship holds generally. It essentially yields T~r², for the classical vibrational period, versus the square of the internuclear distance at different electronic states of a given molecule, which happens to be an approximate relationship known since 1925, but not disclosed so far.

In this article, we determine the quantum mechanical mulitplier appearing next to the Planck Constant in the epression in question to be r/r₀, for electronic states configured similarly, r being the internuclear distance at the given electronic state, and r₀ the internuclear distance at the ground state.

Note that, not much is reported about the quantum numbers of complex systems, in the literature.

@@ Line 17: / Line 17: @@
 Note that, not much is reported about the quantum numbers of complex systems, in the literature.
-[[Category:Scientific Paper]]
+[[Category:Scientific Paper|mass space size period time structured diatomic molecules ii quantum numbers electronic states]]
-[[Category:Relativity]]
+[[Category:Relativity|mass space size period time structured diatomic molecules ii quantum numbers electronic states]]