Atomic Resonant Frequencies

Albert Einstein won the Nobel Price in Physics for his discovery of the relationship between color and atomic structure.  When an element is heated to a critical level, it will produce a specific color which is determined by the size of the atom and its resonant frequency.  Also an element can be excited by radiating it  with its specific color frequency.  This relationship is the basis of spectrographic analysis, a method for determining what any substance is made of.  Mr. Cayce used this phenomenon to excite his Carbon Ash so that it would release the oxygen atoms attached to it.

The mercury quartz lamp Mr. Cayce used with the carbon ash has a maximum output at 254 nm.  The mercury vapor spectrum also has prominent lines within the visible light spectrum at 436 nm (blue), 546 (green), and a pair at 577 nm and 579 nm (yellow- orange).  The wavelengths between 500 nm and 550 nm correspond with the color green.  Perhaps this is why Mr. Cayce wanted the mercury ultra violet lamp filtered through a green glass.  He was exciting the carbon molecule at its resonant frequency.  The output spectrum of the mercury ultra violet lamp coincides with the most responsive frequencies of the Carbon 60 molecule.  Since the UV rays are filtered out when they pass through the green glass, then why would he want to use a mercury vapor UV lamp? In the following reading he explains that other frequencies produced by the lamp are the ones which are used, especially the green part of the mercury vapor spectrum.  Using a mercury vapor lamp and green glass produces an intense green light.  This was probably the most effective way to produce this light using the technology of the time.  Mr. Cayce once said the color of the glass should be "Nile green", which is a yellowish green color.  The spectrum of the mercury lamp shows that Nile green glass is an exact match for the green line of the mercury lamp.