Accurate 432^2 Hydrogen Line…186,624 SOL
Remembering our SOL cycling harmonic hum…from astronomic to anatomical proportion, it’s all about tuning back to our original bi polar pair light signaling coordinate alignment. Following are great simple overviews to help explain solar light wave communication.
Solar Light Wave Guidance:
The Hydrogen Line in Radio Astronomy; Photonic, Nov 2021
“What type of signals are we hoping to pick up with our new radio telescope, what are the frequencies that are available to us, and what objects can we see in those frequencies? To answer that question we need to take a look at the hydrogen atom. Hydrogen is the simplest of all atoms and it accounts for 90 percent of all atoms in the universe. It consists of a single proton in the nucleus represented here by the red sphere and one electron represented by the blue sphere. As subatomic particles, both the proton and electron have a property called Spin, here represented by the arrows. They aren’t actually spinning, instead spin is a type of inherent angular momentum that subatomic particles possess.
When we measure the spin of a proton or electron in a hydrogen atom, the particle is always in one of two states. It’s either down or up- these are the only two values the spin can have. This means that for neutral hydrogen, there are only two possible ways for the proton and electron to align themselves. Either their spin is aligned in opposite directions with the proton being spin up and the electron being spinned down or vice versa, or they can be aligned with their spin in the same direction- either both down or both up.
When the spin of an electron is aligned in the same direction as that of the proton, the electron has slightly more energy than it does when the spin is opposite. The difference in energy is about 5.87 microelectron volts. Of course all matter in the universe tends to want to be in the lowest possible energy state, so this electron is always trying to give up that extra energy. This would involve the spin of the electron flipping from the spin being in the same direction to the opposite direction from that of the proton and this is called a spin flip transition because energy has to be conserved. The difference in energy between the two states is emitted from the electron as a photon. The photon emitted during the spin flip transition has a frequency of 1.42 gigahertz and a wavelength of 21.1 centimeters.
A hydrogen atom in the higher energy state will take about 10 million years before it decides to undergo the spin flip transition. Obviously we’re not going to see this if we wait around in a laboratory looking at one individual hydrogen atom, but because there are an estimated 10 to the power of 80 atoms in the universe (and 90 of those atoms are hydrogen), hydrogen atoms in the universe are undergoing this spin flip transition on a constant basis. Therefore whenever you have a lot of hydrogen gathered in one place such as in the plane of the milky way galaxy, it will constantly be emitting a radio signal at 1.42 gigahertz. This is known in astronomy as the hydrogen line and it allows us to map the location of hydrogen in the milky way.”
Spin-Flip Photonic Signaling Emissions:
The Spin-Flip Background; The Furlanetto Research Group
https://cosmicdawn.astro.ucla.edu/spin_flip.html
Effects of polarons and bipolarons on spin polarized transport in an organic device; Yubin Zhang a, Junfeng Ren c, Guichao Hu a, Shijie Xie. School of Physics, Shandong University, Jinan 250100, ChinabState Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, ChinacCollege of Physics and Electronics, Shandong Normal University, Jinan 250014, China
https://www.sciencedirect.com/science/article/pii/S1566119908000852