© Lloyd

1. The photon was mistaken for the electron, and all of quantum mechanics was based on quantum energy steps on the electron when it should have been based on a quantized photon.
2. Any close look at blackbody radiation should point us at the charge field, since the radiation has always been known to be photonic.
3. Why should all bodies be emitting photonic radiation? Where is it coming from? How does it conserve energy?
4. If atoms and molecules are mainly E/M field bodies, and if they are reprocessing incoming heat and re-emitting it as blackbody radiation, why wouldn't blackbody radiation be composed of ions, especially electrons?
5. Atoms are already composed of electrons, so the most direct thing would be to emit them, right?
6. If the electrons are already quantized, the body should be able to emit electrons at any energy level required.
7. So why photons, and where are the photons coming from?
8. photons don't have to be created, because they already exist in all bodies as charge.
9. Many years ago I surmised that Newton's equation was already unified, that it contained charge, and that G was the transform between the charge field and the solo gravity field.
10. If we take G as the size transform between the two fields — taking the volume of one down to the density of the other — we find that the charge photon must peak at a size G times less than the proton.
11. A simple calculation then shows that average charge photon is in the infrared, with a wavelength of about 2 μm.
12. Amazingly, this is where blackbody radiation also peaks:
13. Another calculation that strongly indicates my theory is correct is the peak of gray body emissivity at .95 of blackbody emissivity.
14. Infrared thermometers are commonly set at .95.
15. The reason real bodies can only approach 95% of a black body is that real bodies are composed of baryonic matter, not just compressed photons.
16. Since baryonic matter is taking up 5% of the energy field, that 5% isn't available to be recycled.
17. So a real body can't be a perfect black body.
18. A perfect black body would have to be composed of compressed photons.
19. The black body would have to be nothing but charge.
20. Since that is impossible (as far as we know), real radiation hits a limit at 95%.
21. For instance, if you take this link, you find that soil may exceed 95% emissivity. Soil.
22. Turns out, the soil that exceeds .95 is soil still in the ground, and the IR thermometer is of course pointing down to the Earth to take the reading.
23. By my theory, that must skew the measurement, since charge is coming out of the Earth.
24. The Earth itself is recycling charge, so soil still in the ground will be transmitting this charge recycling through the Earth.
25. It will be asked of me, "If blackbody radiation is charge, and charge peaks in the IR, then why do very hot bodies peak in the visible?"
26. This is explained very simply by my quantum spin equation, by which particles stack on new spins at higher energies.
27. I have shown this is the physical and mechanical explanation of quantization, but the fundamental quantized particle is the photon, not the electron.
28. Since the photon gains energy via quantization in this way, at a given charge energy level, the charge photons will stack on another spin, becoming more energetic.
29. They each then have more radius, more angular momentum, and more of what we now call frequency.
30. In short, they move up the energy scale, moving from IR to visible.
31. Blackbody radiation is defined [in Wikipedia] as E/M radiation that was converted from thermal energy.
32. But if thermal energy isn't E/M energy, what is it?
33. We will be told it is molecular or atomic energy from motion, as in wiggling, Brownian motion, etc.
34. But what causes that? What is heat if not some sort of E/M energy?
35. Blackbody radiation is not E/ M radiation, since we should save that term for ionic radiation.
36. What we have here is photonic radiation, as I reminded you above.
37. Well, I have shown that heat and thermal energy are also photonic.
38. They are an outcome of an underlying charge field, and the charge field is the same as the photon field.
39. Planck's spectrum is just an extended version of the charge field.
40. The charge field IS the photon field IS the light spectrum.
41. Heat comes into a body from the outside, via the charge field.
42. This raises the energy of the body by increasing the body's internal charge density.
43. The body then re-emits a part of this excess energy in the light spectrum, which is also charge.
44. Heat may be carrying ions, since charge normally does.
45. But heat is [wrongly] defined by the charge stream carrying it.
46. The Draper point also confirms my analysis, since my quantized photon requires that there be a temperature at which the charge photons stack on another spin.
47. In other words, we don't see a continuum or a slow change.
48. We see a field jump at a given energy level, and the Draper point is one of those energy levels (798K).
49. You can also see clear evidence of this from the colors at higher temperatures.
50. Blackbody radiation doesn't move continuously through the visible band, giving us yellow, green, cyan, blue and purple.
51. Instead, it jumps from IR to red to white, with only a mix of red and white between.
52. More evidence comes from the fact that the light from very high-temperature blackbody radiation never becomes violet or disappears into the UV and above.
53. It just becomes whiter and more intense, seeming to us to turn a blue-white.
54. However, this blue-white should not be confused with prismatic blue, since nothing about the radiation matches the energy of prismatic blue.
55. It would seem that intense white appears slightly bluish to our eyes, perhaps from the complete lack of reds.
56. The reason this last fact confirms my theory is that, given current theory, we would expect the peak to move above the visible.
57. If the quantization of energy matched current models, there would be nothing to stop the peak from moving above the visible at very high temperatures.
58. What keeps it from doing so in my quantum spin theory is that the quantization hits a limit when the IR photon has stacked on four spins.
59. It can stack on a fifth, but at that point the particle is no longer a photon, so it doesn't push the peak above the visible.
60. The radius of the charge photon is now so great that the photon cannot maintain c.
61. It suffers too many collisions in the field to maintain c, and its linear velocity drops, becoming after that dependent upon its mass and its field surroundings.
62. In short, the photon becomes an electron.
63. This drop in velocity prevents the radiation peak from continuing to climb.
64. Instead, a feedback mechanism is created, and the high temperature strips spins from newly created electrons about as fast as they can be created.
65. This holds the peak at a limit, and any more added photons (or added temperature) will only increase the density of blue-white radiation.
66. If thermal energy is molecular motion, then larger molecules should have more inertia — more resistance to increased energy or temperature — than smaller molecules.
67. Atomic weight should matter, as should the density of the substance.
68. The only way the density and mass of the matter couldn't matter is if the matter field weren't the fundamental field here.
69. But in my theory, the photon is quantized.
70. The photon has energy levels due to spin stacking, and that is what we are seeing here in this blackbody problem (and all other quantization problems).
71. According to current theory, different elements have different electron configurations, and therefore electrons at different energy levels.
72. If the orbiting electrons were involved in this quantization, we should see the elemental and orbital energy signatures. But we don't.
73. The mainstream admits the quantization in blackbody emission follows pretty much the same curve for all elements or substances, which is strong evidence the electrons are not involved.
74. This is precisely why they tell you that a blackbody cavity can be taken as a photon gas.
75. No orbiting electrons in a photon gas, are there? So where does the quantization come from?

(From: Blackbody Radiation is the Charge Field by Miles Mathis)