Proposal to test the Non-Greenhouse Gases for IR Radiation with the Raman spectrometer

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By Greenhouse Theory, 99% of the dry atmosphere, nitrogen (N2) and oxygen (O2), (the non-greenhouse gases), are assumed not to absorb or emit infrared radiation. They are claimed to gain their heat energy from molecular 'collisions' with the 1% special heat-trapping greenhouse gases. This process of 'collisions' implies thermal conduction of heat. 

Four things: 

  1. foundation radiation physics/ quantum mechanics claims all matter with a temperature radiates infrared light,  
  2. air is a poor thermal conductor, one of the poorest known (0.026W.m.K.),
  3.  if the, for instance, 0.04% CO2 did transfer heat by conduction to all the 99% nearly instantaneously, its claimed heat-trapping properties would have to be extraordinarily special to share this gained energy equally, not just special, and
  4. if the air did transfer heat by collisions, we would live in a hell of heat as we would feel the heat of every matter directly through the air. 

If the greenhouse theory were true, with the ambient CO2 of around 400ppv, the following demonstration could not be conducted.  For one, there is no way these men could stand by this solar furnace focal point of over 3500C when "..there are no known materials that could resist this." heat. They would be roasted. 




When the wood passes through the focal point, according to greenhouse theory, the CO2 released (maybe 15%) would transfer its heat to all the air, and the heat transfer would be insufferable if true. It is not true. 

Raman spectrometer N2 temperature test after radiation. 

The (CARS) Raman spectrometer can measure the temperature of gaseous nitrogen and oxygen by exploiting the physics that contradicts and refutes greenhouse theory. N2 and O2 do have infrared emission spectra; they are radiated in the operating process of CO2 lasers and measured.

By the following diagram, I would like to point the laser straight up from under - to catch if there is any convection - through IR radiated air at a solar focal point or similar. We wouldn't even need a tank; the Raman spectrometer measures all the gases, H2O, O2, N2, CO2, we could 'spray' pure N2 over the focal point as they do water in the demonstration. 



The CARS unit measures the Raman scattering of the laser photons off the air molecules to infer the temperature. However, as I have learnt, this measurement has problems with 'noise', so it will not be easy. 

N2 is locally radiated, but it is not transferred. Only the Raman CARS can test this.

I am currently in contact with a retired scientist in Switzerland who has a 'rotting' Raman CARS in his lab he used in the 90s on similar but not exact studies. 

What I am asking has not been conducted, and it needs to be done. 

A positive result would mean completely redefining our understanding of the atmosphere in accordance with quantum mechanics.

To be clear (and this is the rebuttal I am receiving), I am not testing for a heating effect from the Raman effect in the atmosphere; there is no such effect. I am using the Raman spectrometer for its intended purpose: to measure the quantum predicted emission spectra line of N2 and others and its temperature. 

Supporting Papers and links: 





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