The spacecraft’s findings support the theory of electric universe. The MESSENGER spacecraft enteredorbit Mercury in March 2011 along a nearly eight billion-kilometer orbit. From then until 2015, it sent out hundreds of close-up images that revealed features and topography that confirm Mercury’s relationship with other celestial bodies in the solar system.

Spacecraft’s findings support the theory about the electric universe

The morphology of its surface is very similar to other planetary bodies, from which it would be difficult to distinguish. Former electrical activity on Mercury is evident in several places across the planet. Indeed, it could be said that the whole planet has nothing but electrical effects. Engraved furrows radiating out of some craters, such as Firdousi, mark the path of countless electric fibers that danced a fiery dance across the surface. On Earth, these fibers would represent the largest lightning strikes ever observed.

The landscape that surrounds Firdousi would be difficult to reproduce in the laboratory if electricity did not enter the image . However, not the electricity needed to operate a compressed air cannon firing hypersonic projectiles, but the electricity needed to operate high voltage discharge.

In an experiment in the “Vemasat” laboratories, Dr. CJ Ransom was the same kind of etched furrow by shocking a thin layer of magnesium silicate for five seconds with a discharge of 120 milliamperes and a voltage of 1,200 volts. He thus created radial grooves on a small scale, which are equivalent to grooves on Mercury on a large scale. Nobel laureate Hannes Alfvén believed that electrical ( plasma ) phenomena can be scaled by up to 14 orders of magnitude. Because the electric arc consists of rotating fibers, if electricity were involved in the development of Mercury, it would manifest itself in many ways.

One of these ways would be a plasma “drill” that would cut through the steep side walls of the crater, while sometimes leaving a “pinched” mound in the middle. Multiple fibers would cut through one crater in another, often with one or more craters at the edges. Firdousi, among dozens of other large craters on Mercury, agrees with this finding.

What is most remarkable about Mercury and other members of the solar system are the numerous chains of craters that are abundant throughout the population. From Phobos to Phoebe, from Mars to Miranda, the planets and moons are dotted with holes that stretch in long lines, sometimes hundreds of miles.

The usual explanation is that a string of meteoroites crashed into them , one after the other. Despite the necessary coincidence for this effect, the absence of deformation in the adjacent crater walls calls this theory into question. Add to that the twists, turns, loops, and braids that can be seen in many of them, and the idea that these features were caused by stones falling from the Universe is falling apart. Anyone who has made a device for making an electric arc called the “Jacob’s Ladder” knows how many craters could have been created.

The “Jacob’s Ladder” is constructed by placing a rigid copper wire on each neon transformer stand .and then they bend towards each other until they form an ever-expanding letter “V” from the bottom up.

When the current is turned on, the electric arc begins at the lowest level of the letter V and then rises up to the top, extending through the widening gap until it ruptures with a burst to start again immediately. If a piece of paper is held between the two arms V as the arc moves upwards , a series of longitudinally burned holes will appear on the paper.

The electric arc passing through the conductive medium varies in force from millisecond to millisecond, so that instead of smooth channels it burns strings of craters. The “smooth” channels we see on many objects are actually chains of craters, which are stacked so tightly that they can no longer be distinguished. There are several examples from the MESSENGER spacecraft that reveal Mercury’s catastrophic past.

Did the tectonic and volcanic forces create wide, parallel ditches on the moon?

The moon has witnessed catastrophic devastation in its past . Its surface is intersected by giant craters, wide and deep valleys and many kilometers of furrows. Conventional theories assume that the Moon underwent intense selenological activity at the beginning of its history. The grooves and shifted slip breaks, known as “depressions”, are said to be the result of slow crustal movements similar to those caused by earthquakes.

This theory assumes that the Moon was born long ages, perhaps billions of years or more, and has not changed much since then. Most scientific theories are narrowly defined. They are based on what is observed on Earth and use this data to model formations observed on other celestial bodies. However, since there is no evidence that the Moon was once subject to tectonic activity, the theory of the electric Universe suggests that the idea be reversed: structures in the Universe should model what is on Earth.

A NASA press release states that the lunar depression was formed during the expansion of the lunar crust. This “stretching” created two parallel breaks, which caused the surface between them to sink into the valley. Thomas Watters , lead author of an article on the subject, which later appeared in the journal Nature Geoscience, said:

“The depression tells us that the shrinking forces of the Moon have sometimes been surpassed by the forces acting to expand it. This means that the contraction forces shrinking the Moon cannot be large, otherwise a small depression would never have formed.”

Similar features are observed wherever telescopes and satellites look. A reasonable hypothesis would show how airless, frozen bodies can compare to hot, humid planets such as Earth. Because consensus scientific reports give little weight to electricity, even though it is many orders of magnitude stronger than gravity, heat shock or bark propagation is nothing compared to the effects of an electric shock of several trillion joules.

Selenologists have few tools to help them understand planetary scarring , because no electricity courses are needed in their field . Plasma physicists realize that charged objects immersed in an electric field form “Langmuir shells,” named after plasma pioneer Irving Langmuir . Langmuir mantles isolate charged objects from each other inside double layers.

If charged objects are planets or moons, they may be surrounded by double layers of plasmaspheres . Laboratory experimentsshow that when the hub casings collide, they cause an electric breakdown. A sufficiently large charge flow initiates an electric arc. If the smaller charge mantles in the lab behave a certain way, then larger planetary mantles could trigger gigantic lightning.

Such interplanetary discharges could tear rock layers, cut surfaces with the effect of a plasma “torch” and generate intense heat through electromagnetic induction. The moon has no plasmosphere. However, this does not mean that he has not been surrounded in the past ammunition casing. The Earth’s plasmosphere also surrounds the Moon during part of its orbit, so the electric shock effects enveloping our planet could easily include it. Rather than expanding or collapsing, the ridges and depressions on the moon could have been cut by electric shocks sometime in the recent past.

Glass mountains

According to the consensus, all valleys are caused by water erosion and solitary peaks must be volcanoes. The various peaks in the Greenhouse Mountains are thought to be remnants of volcanoes that erupted long ago, although there is little evidence of basalt, lava flows or calders that would normally be expected. In fact, the main peak of Mount Beerwah comes into a point structure. Its surface is a type of sandstone that is relatively soft. The bottom is smooth, as if it were once molten, while above the surface turns into columnar structures that are twisted.

On the north side of Mount Beerwah lacks the part that reveals its heart. This is where the surprising features are revealed. The interior is made of very soft white gypsum- like rock. When weathered, it forms a talc -like mass at the foot of the rock. A honeycomb structure made of iron stone, which is harder than sandstone on the surface of the summitis inserted into the soft rock this structure is an anomaly that does not fit into the theory of volcanoes and is difficult to explain.

However, if an electric current in the formis considered as an alternative to wind and rain weathering plasma arcs, makes the composition of the vertex more meaningful.

If Mount Beerwah, according to experts, is the remnant of a volcano that has been weathered for millions of years, soft white rock would have accumulated at the foot of the cliffs. Estimation of weathering by the amount of “talc” residues indicated a maximum of several thousand years , not millions of years.

Another interesting aspect of this area is that the line of mountain peaks is located near the existing coast. Their geographical location raises the question of whether plasma discharges have also deepened the ocean basins. Origin of coastal topography was associated with such discharges. Almost all features of the Earth show the effects of plasma machining.

In order to be visible, there must be an internal model. When viewed from an electrical perspective, the Earth’s geology reveals a uniquely deformed landscape that may have formed in a short time.