Space plasma crack

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Space Photo Screensaver 1. Lightspeed Screen Saver 9. The angles in their layers and contours is pure information about their creation, because information is always a waveform, and the mountains store the waveform.

The shock wave, and shock wave reflections, form an electric field across the walls of the wave in the manner of a capacitor. A double layer forms on the interfaces with a dielectric field between. The charged layers can be the same or opposite polarity to the charge of the dust being deposited, leaving ether a void, or hardened rock. A hardened seam will have more conductive material, like the quartz in rock veins, than the surrounding country rock-matrix.

Mineral bearing veins, for instance, bear conductive minerals like gold, silver and copper because these conductive materials were attracted by the electric field of the shock wave either as a vapor from the atmosphere, or by diffusion through the ground or by transmutation, but that is over my head.

Diffusion through the ground is how consensus theory works, with the attractor being hydrothermal venting. The quartz veins in the images of granite were created by an emergent effect of shock waves, called traveling waves. Note there are four wide quartz veins see large image in two pairs that parallel each other diagonally across this granite face.

Traveling waves are semi-stable reflected waves that migrate through a shock wave structure due to instabilities in the bubble. The even vertical lines that appear in Figure 10 are examples in a steady wind.

But shock wave bubbles can wobble just like soap bubbles, producing instabilities as wind speed and direction varies. They move in harmony to the shock wave frequency in repeating patterns. That is why there is a pair-of-a-pair of similarly structured, yet highly complex repeating forms in these rock veins. The next image shows clastic dikes in Washington State.

These dikes are vertical-to-diagonal intrusions in a sedimentary hill exposed by road cut. Each dike is layered, vertically, with different fineness of sediment graded from silt to gravel, in each separate layer. The sediments inside the dikes are completely different material than the hill they intrude in. And that is exactly right. Each layer in this dike was a separate funnel of air pulling dust down from different regions of the shock wave bubble, where different grades and types of rock were flowing in segregated jet stream winds.

The cracks, dikes and veins just shown were produced in the very bottom of a shock wave structure like the one shown in this image. They formed in the turbulent back-end of the separation bubble, a result of friction where the wind literally scraped the ground. Mountains like Everest, the Matterhorn and thousands of lesser peaks were formed by dust filling the entire lambda foot structure, forged by winds and electric potentials that are nearly incomprehensible.

Supersonic winds had to wrap the entire planet. Earth looked like Jupiter, only a lot worse. Higher winds moved slower, circulating positive charge in a halo over the concomitant destruction and creation below. Hence the Ouroboros. Every feature points to the actions upstream in the current path.

That is why the true creation story is knowable. The patterns remain that tell the story. Frequencies, harmonies, wavelengths and wave-guides. Shock waves are wave-guides. Everything is electric. Everyone needs to know this, the sooner the better. I accept that I am a layman, but the geology of the Earth is billions of years old. Mountains are not. If shock waves and wind built them, the layers within current mountains would show evidence of their form.

Further, the early years your thesis should have produced chains of mountains all over the shop, pretty well everywhere! Had that happened it could not leave relatively flat layers of geological eras.

This is clearly not the case, the layers visible are formed mainly of fairly level older strata. No evidence of mountains billion of years old has been found. On the contrary, there are folk tales of mountains suddenly appearing, e. I cannot see how your thesis creates mountains. Land being forced up creates high cliffs and plateaus, it does not build any mountains, let alone thousand mile long chains of high mountains, each hard by the other, or make smaller ones literally erupt out of their sides.

Seen as a graph it looks like an elongated radio wave or a heart monitor wave. Whilst wind and ground shock play a part, surely the main actor must be enormous charges of electricity during a near planetary collision. Wind may well enhance the sharpness of their pointy tops, but only if the characteristic general cone shape was already in being when they formed.

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You are commenting using your Facebook account. Notify me of new comments via email. Notify me of new posts via email. Figure 1. Thermal cracking? Figure 2. Black, burnt, chipped and chemically altered rock where lightning struck sandstone. Note the lightning streak angle is at odds with the vertical water streaks.

Figure 3. Diagonal seam in sandstone tetrahedron due to a shock wave Figure 4. The windward face of a tetrahedron displays the effects of multiple shock wave reflections. San Rafael, Utah. Figure 5. Frozen in time, off-gassing from a shock wave. Figure 6. A plasma is a gas that is so hot that some or all its constituent atoms are split up into electrons and ions, which can move independently of each other. Because they are made up of electrically charged particles, plasmas can be strongly influenced by electrostatic and electromagnetic fields and forces, which can lead to very complex and interesting behaviour.

Plasmas are found throughout the Solar System and beyond: in the solar corona and solar wind, in the magnetospheres of the Earth and other planets, in tails of comets, in the inter-stellar and inter-galactic media and in the accretion disks around black holes.

There are also plasmas here on Earth, ranging from the inside of a nuclear fusion reactor to a candle flame. In the Space Plasma Physics Group, we study plasmas in the Earth's magnetosphere and the solar wind, and what happens when they interact. Despite what a lot of people think, space isn't actually empty, and the Earth's magnetosphere is no exception!

The magnetosphere is full of plasma of many different temperatures and densities - though most of it is too tenuous to see with the naked eye or even with a telescope.