Do convection currents and vibrating magnetic field lines create the dynamic phenomena observed on the Sun?
According to the thermonuclear fusion model of the Sun, hydrogen in its core is crushed with so much force that it is converting to helium, releasing tremendous amounts of energy. The core’s temperature is thought to be 15 million Celsius, with compressive strain greater than 340 billion times Earth’s atmospheric pressure. A common metaphor used to illustrate the process is to imagine millions of hydrogen bombs exploding all at once within a confined space: 700 million tons of hydrogen are said to be converted into helium every second.
The Sun’s surface is known as the photosphere. Above that surface layer is the chromosphere, and above that is the corona, the outermost part of the Sun’s visible atmosphere. The photosphere averages 6000 Celsius, while the corona can be as much as two million Celsius! This is the great mystery that has encumbered researchers. How is it that the hottest region of the Sun begins at an altitude of 4000 kilometers and extends over a million kilometers from its surface without any significant temperature drop?
Many ideas have been proposed for how this steep temperature rise occurs. Some research groups have concluded that it is the “rearrangement of magnetic field lines,” otherwise known as “magnetic reconnection,” that is causing the heating. Both the SOHO and TRACE satellite observatories have detected small, rapidly changing magnetic regions on the Sun’s surface.
The above is sourced from Thunderbolts and written by Stephen Smith.
Another potential explanation for the solar corona’s extreme thermal radiance is that convection on the Sun’s surface causes magnetic field lines to oscillate. As the field lines move up and down, waves travel along them, eventually moving outward into the corona where (presumably) sufficient kinetic energy heats it up.
In the electric model of stars, the Sun is a positively charged electrode in a circuit, while the negatively charged electrode is located far beyond the planetary orbits. The “virtual cathode” is known as the heliopause.
As the electric model relates, sunspots, flares, coronal heating, and all other solar activity is most likely a result of fluctuations in electricity from our galaxy. Birkeland current filaments slowly rotate past the Solar System, supplying more or less power to the electric circuit powering the Sun.
The electric current flowing out of the Sun is balanced by the current flowing into it, so perhaps the changes in temperature indicate the magnetic field polarity and the strength of the electric field. If the Sun is connected to the rest of the galaxy by Birkeland current “transmission lines,” then its puzzling characteristics with respect to conventional interpretations are most likely demonstrating the fluctuations in current arriving from the Milky Way’s electric generator.
The Sun’s inverted temperature gradient can be explained by the Electric Star theory because it conforms to an electric discharge within the z-pinch zone of intergalactic Birkeland current filaments. The Sun is a gigantic electric arc, not a ball of hot hydrogen gas. Therefore, the energy of the Sun is focused from outside and not expelled from inside.