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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If we accept that stars with their attendant planets and their moons move around in various configurations<br />
as independent systems in space and that interactions between these star systems will inevitably have gone<br />
on against a scale <strong>of</strong> time we cannot imagine, then we have a basis on which to consider how the ‘electrical<br />
capture’ <strong>of</strong> stars, planets and moons can take place. Remember that I previously mentioned a bubble <strong>of</strong> electric<br />
charge existing around the solar system. This will apply to every star system and the bubble itself will extend far<br />
beyond any planets that a star system may have. This bubble is given the name ‘heliosphere’ or more generally,<br />
‘astrosphere’, and its outer edge in contact with deep space is called the ‘heliopause’. Due to the double layer<br />
effect also previously mentioned, the heliopause is where the greatest voltage difference will exist between any<br />
star system and deep space.<br />
Interacting star systems, one more dominant than the other.<br />
(This image does not represent the fuller story) © author<br />
When the heliopauses <strong>of</strong> two star systems come into<br />
contact with each other, the ‘action’ begins. The star<br />
system with greatest level <strong>of</strong> charge will electrically<br />
dominate then manipulate all <strong>of</strong> the bodies within<br />
the less powerfully charged system. The ‘touching’<br />
<strong>of</strong> heliopauses brings about an immediate transfer <strong>of</strong><br />
positive charge from the less dominant to the more<br />
dominant system, so the star in the less powerful system will quickly lose its glow and stop looking like a star<br />
since it is negatively charged in relation to the star <strong>of</strong> the dominant system. The less dominant star then becomes<br />
a gigantic comet, shedding matter in an effort to regain electrical equilibrium. Then, it and all its original planets<br />
are swiftly ‘captured’ by a charge exchange mechanism within the original dominant star’s ecliptic plane. That<br />
same charge exchange mechanism will further manipulate all the new arrivals into electrically and gravitationally<br />
stable orbital locations within the new star system. Due to its previously large glowing plasmasphere then being<br />
‘switched <strong>of</strong>f’ the much smaller remnant body <strong>of</strong> the captured star will find itself treated the same as the planets<br />
that once were its own. It is possible, in fact likely, that it would end up having the appearance <strong>of</strong> a giant gas<br />
planet such as our own Jupiter or Saturn, possibly complete with debris rings leftover from the encounter.<br />
The scene is therefore set, so consider our own Sun thousands <strong>of</strong> years ago with whatever planets it had at<br />
the time, and a brown dwarf system with its own planets coming into electrical contact with it. If we apply<br />
the above explanation then what we see today is an apparently peaceful snapshot <strong>of</strong> planets and moons that<br />
will have experienced great chaos in the past. An intriguing proposal now surfaces, one that may explain the<br />
particularly strange makeup <strong>of</strong> our solar system. This proposal goes further than the hard-science <strong>of</strong> electric and<br />
plasma cosmology to seriously consider the recorded evidence that exists from ancient times <strong>of</strong> cataclysmic<br />
events <strong>of</strong> epic proportion that occurred in those days.<br />
104 | The <strong>Electric</strong> <strong>Universe</strong> answers I see