The Selenelion Proves the Lunar Eclipse is NOT Caused by The Earth’s Shadow

The Selenelion occurs when you can see the Sun and Moon above the Earth’s horizon at the same exact time while the Moon is eclipsing on its own. The scientific explanation is it due to being atmospheric refraction of light.

However, the Moon can be seen being eclipsed by a shadow that travels OVER the moon from the TOP down. The atmospheric refraction explanation of pseudoscientists of modern Heliocentricity requires the shadow to progress from UNDER the Moon, but what actually happens is that the shadow progressing downward refutes the light fraction explanation It’s the complete opposite of what they claim.

Impossible "Selenelion" Eclipse, December, 2011

FLAT EARTH Selenelion from Mauna Kea Hi January 2019:

Hence, what we actually see is geometrically impossible on a spinning globe model.

The Components of the Heliocentric Lunar Eclipse Model
The Earth’s Penumbra and Umbra:

The Penumbra is the region in which only a portion of the light source is obscured by the occluding body. An observer in the penumbra experiences a partial eclipse. An alternative definition is that the penumbra is the region where some or all of the light source is obscured (i.e., the umbra is a subset of the penumbra).

According to the Heliocentric Model, The Umbra is a shadow's dark core. Imagine a light source and an object casting a shadow. If you are standing within the umbra, you will not be able to see any part of the light source as the object blocks all direct light rays. During a total lunar eclipse, the entire Moon enters the Earth’s umbra. (Shadow), as the Heliocentric story goes.

Lunar Eclipses do NOT Prove the Earth is a Globe:

Lunar Eclipse at Sunrise: Selenelion viewed from Cahokia Mounds

The Earth’s Penumbra and the Reddish Moon at Lunar Eclipse:
Ok, so, in the Heliocentric Model, the Earth’s shadow has two parts: the umbra and the penumbra. The umbra is not pitch black because a small amount of the Sun’s energy directly shines within the penumbra of the Earth’s atmosphere. As light passes through the atmosphere, the blue colors are scattered out of the path. Those with longer wavelengths, like red and orange, pass through the atmosphere. This red-orange light is then bent or refracted around Earth, hitting the surface of the Moon and giving it the reddish-orange glow that total lunar eclipses are famous for. Subsequently, if our planet had no atmosphere, then the Moon would be completely dark during a total lunar eclipse.

Rayleigh Scattering And Cause of The Blue Color in The Sky:

Why is the sky blue? The short answer: Sunlight reaches Earth's atmosphere and is scattered in all directions by air molecules, water molecules, and dust and gases particles in the air. Blue light is scattered more than the other colors because it travels as shorter, smaller waves. This is why we see a blue sky most of the time. The amount of bending of the light depends on the angle of incidence and on the indices of refraction of glass and air, which determine the change in speed. This is Snell's Law, or the Law of Refraction.

Sunlight reaches Earth's atmosphere and is scattered in all directions by all the gases and particles in the air. Blue light is scattered in all directions by the tiny molecules of air in Earth's atmosphere. Blue is scattered more than other colors because it travels as shorter, smaller waves. This is why we see a blue sky most of the time.

The longer explanation: Rayleigh Scattering causes the blue color of the daytime sky and the reddening of the Sun at sunset. Rayleigh scattering, named after the nineteenth-century British physicist Lord Rayleigh, is the predominantly elastic scattering of light or other electromagnetic radiation by particles much smaller than the wavelength of the radiation. For light frequencies well below the resonance frequency of the scattering particle (normal dispersion regime), the amount of scattering is inversely proportional to the fourth power of the wavelength.

Scattered blue light is polarized. The strong wavelength dependence of the scattering (~λ−4) means that shorter (blue) wavelengths are scattered more strongly than longer (red) wavelengths. This results in the indirect blue light coming from all regions of the sky. Rayleigh scattering is a good approximation of the manner in which light scattering occurs within various media for which scattering particles have a small size (parameter).
—Wikipedia

Rayleigh Scattering Sunsets

The explanation for the reddish tints seen in the sky at either end of the day lies in Rayleigh scattering. As it passes through layers in the atmosphere, shorter wavelength light is scattered more than longer wavelength light.

Sunlight is made up of all the colors of the visible light spectrum – red, orange, yellow, green blue, purple, which may seem familiar as all the colors of the rainbow.

Rainbows appear when the different wavelengths get broken up through refraction and scattering in the atmosphere. Basically, as the light passes through different densities in the air, the light bends, kind of like it does in a prism and bounces off tiny particles that are in the air. This also explains why, during the day, the sky is blue. The particles that are in the atmosphere scatter sunlight so that the blue wavelengths are not absorbed but reflected.

At sunset the same things happen, but because of the angle of the sun and the volume of gas and therefore the density of gas that the light passes through changes, the sky takes on a reddish glow from the longer wavelengths in the visible light spectrum.

Is a Reddish Moon at Lunar Eclipse Probable?

Ok, but the question remains, after the blue light from the Earth’s atmosphere is scattered into oblivion, leaving predominantly longer red wavelength light, could this refracted red wavelength be transmitted 294,000 miles to the Moon to create the reddish Moon that we observe during a Lunar Eclipse? Is a reddish Moon at lunar eclipse probable? Well, what if you are standing on The Earth? Are reddish sunsets probable? Yes, of course they are. The Sun’s rays are refracted, and you may see a reddish sunset.

That makes sense. But, standing on the Earth, you are just a few thousand miles from all that atmospheric layering. That is very close, compared to refracting all the way to the Moon and then bathing the Moon in red light. It is possible, but is it absolutely an uncontestable fact? Highly debatable. And again, this model assumes the Sun is huge ball 94 million miles away, which has never been proven. Our eyes tell us the Sun is very close to the Earth, in the Earth’s atmosphere, and the same size as the Moon. Again, it’s the tail wagging the dog error. One has to go against everything his senses tell him to imagine a distant Sun, which is necessary for the Heliocentric Lunar Eclipse Model to work.

The Heliocentrist Debunk of Flat Earth Selenelion Fails Because Many of Them Are Over 15 Degrees High: The Heliocentric Model Fails To Explain This Apparent Position by Over 9 Degrees:

In other words, the Sunlight’s refraction around the Earth to create a reddish Moon at Lunar Eclipse is no proof of a Heliocentric Model. Rather it ASSUMES the Heliocentric Model first, and then reverse engineers the variables it needs to make it work. It a masterpiece of reverse engineering, as opposed to an empirically observable model. That is allowed in science but calling it a fact is not a scientifically allowed statement.

In other words, the Sunlight’s refraction around the Earth to create a reddish Moon at Lunar Eclipse is no proof of a Heliocentric Model. Rather it ASSUMES the Heliocentric Model first, and then reverse engineers the variables it needs to make it work. It a masterpiece of reverse engineering, as opposed to an empirically observable model. That is allowed in science but calling it a fact is not a scientifically allowed statement.

In other words, the Heliocentric Model is still a highly debatable theory.

Flat Earth Video 53 - Can You Say Selenelion? (1080hd) - Total Lunar Eclipse 2018 (1080hd):

An Alternate Explanation

The Moon does not completely darken as it passes through the umbra because of the refraction of sunlight by Earth's atmosphere into the shadow cone; if Earth had no atmosphere, the Moon would be completely dark during the eclipse.”
—Wikipedia

Though Wikipedia’s definition falsely assumes its cause of a Lunar Eclipse, it does confirm one important fact. “The Moon does not completely darken” as it goes through what has been wrongly labelled a “Lunar Eclipse.” The Moon never fully disappears as if the Earth is blocking the light of the Sun completely in the umbra shadow of The Earth, and refracting red light to make it appear red. This is just a science fiction explanation from science fiction NASA and science fiction writers in Astrophysics.

So, what is really happening? Well, here is an alternative theory. You decide for yourself which explanation seems more plausible.

Ok, a Lunar 'eclipse' happens at night. When it happens, the Moon turns orange in color. This is caused when the Sun and Moon line up with the center of the disk Earth. The Sunlight goes through the strong magnetic field of the north pole, and the sunlight turns orange. And that light then hits the Moon. Since the sunlight is orange, it makes the moon appear orange as in this image. The Moon must be at same altitude as the Sun in order for this to happen. That's why it doesn't happen very often and is a rare event. Thus, as you can see, the phenomenon of the 'orange moon' is not an eclipse at all but is caused by the North Pole's magnetic field.