A Beginner's View of Our Electric Universe - New
A Beginner's View of Our Electric Universe - New
A Beginner's View of Our Electric Universe - New
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The way we do this today, however, is by using special telescopes and detectors that are able to ‘see’ the<br />
radiation that stars and other bodies and events give <strong>of</strong>f. Much <strong>of</strong> this detection takes place using infrared (heat)<br />
radiation, but still more is achieved by looking for other wavelengths as well like radio, ultra-violet, X-ray and<br />
gamma ray emissions. (Noteworthy: Some researchers say that many other stars like our Sun have at least one<br />
companion body. <strong>Our</strong> own Sun is rumoured to have one that has not been observed for thousands <strong>of</strong> years, so<br />
its existence has never been confirmed or in any way acknowledged by modern standards. It has been said that<br />
it, along with its own attendant planet(s) are on a long elliptical orbit that sees them passing through the solar<br />
system very rarely. This dwarf star has been assigned a variety <strong>of</strong> names over time such as, Planet X, Marduk,<br />
the 12 th Planet, Nemesis, The Destroyer, Nibiru, and others. When looked further into there is confusion around<br />
the actual configuration <strong>of</strong> the main star and any planets it may have, but those who study this subject generally<br />
support the model <strong>of</strong> a brown dwarf star having at least one planet. Whatever the facts may be, it has to be said<br />
that a search for this brown dwarf has been and is being conducted on the basis that by the law <strong>of</strong> averages, a<br />
body such as this may actually exist, and that its long orbit around the Sun, which has been said could be 3,600<br />
years or more, is the reason why we have no formal record <strong>of</strong> it. [More on stars [6-22a] [6-22b] ])<br />
It is not just relatively small stars that can have lowpower<br />
levels; there are much larger stars which also<br />
appear not to be operating in arc mode. The volume<br />
their plasmaspheres will encompass will be gigantic<br />
around what must be their relatively tiny cores.<br />
An example <strong>of</strong> this is the ninth brightest star in the<br />
night sky which has been classed as a red giant; this<br />
is Betelgeuse in the Orion constellation. Estimates<br />
have been made <strong>of</strong> the diameter <strong>of</strong> this star and it is<br />
typically quoted as being around the diameter <strong>of</strong> the<br />
orbit <strong>of</strong> Jupiter. Can you imagine a star <strong>of</strong> almost a<br />
billion miles across?<br />
Estimated size <strong>of</strong> Betelgeuse and its location Credit: NASAJPL-Caltech UCB<br />
The EU model <strong>of</strong> stars suggests that inside the large dimly glowing plasmaspheres (atmospheres) <strong>of</strong> brown<br />
dwarf stars, the space between their solid core and the inside <strong>of</strong> their layer <strong>of</strong> glowing plasma would be the<br />
ideal environment for life to thrive. Although much larger and hotter than a brown dwarf, Betelgeuse has been<br />
proposed as a candidate for having planets orbiting within its glowing plasma shell. Furthermore, as I mentioned<br />
in relation to Jupiter and its moons, it is said that planets in this circumstance would likely experience constant<br />
temperature and light exposure and they would not be subject to seasons like we are here on Earth.<br />
111 | The <strong>Electric</strong> <strong>Universe</strong> answers I see