Do the Gas Giants in Our Solar System Have Solid Cores?

Contrary to the popular belief, the gas giants of our solar system, such as Jupiter and Saturn, do indeed possess solid cores. These cores, hidden beneath layers of gas and liquid, are crucial to understanding the formation and inner workings of these massive planets. This article explores the existence of these solid cores and what we know about them.

The Misconception of Gas Giants

The term 'gas giant' is somewhat misleading because these planets are not entirely composed of gas. Just like the Sun, which also has a solid core of plasma, Jupiter and Saturn have solid crusts that are necessary for their stability and formation. The name generates a visual image that could not be further from the truth, as these planets contain layers of dense materials, including ice and rock, underneath their gaseous atmosphere.

The Inner Structure and Formation of Gas Giants

Although the outer layers of these planets are dominated by gases, the inner regions are quite different. The inner mechanism of Sun and giant planets is remarkably similar, driven by electromagnetic phenomena that play a significant role in their formation and evolution. The concept of a "theory of Spherical Vortex" explains the direction of energy flow in the fourth dimension, which determines whether a massive object is absorbing or emitting energy.

Jupiter and Saturn as Absorbers of Solar Energy

These gas giants are not just passive recipients of solar energy. Instead, they absorb solar energy from the solar wind, which is electromagnetically polarized. This process acts as a "Solar Mass Transplantation," where the planets gain mass over time by absorbing energy. The electromagnetic polarization of the planets, including Earth, is a key factor in their growth.

Understanding the Process of Growth and Formation

The presence of a Spherical Vortex is a telltale sign that a planet is in a state of productive growth. Where a Spherical Vortex is active, a controlled black hole exists in the core, responsible for the electromagnetic polarization and periodic magnetic reversals. This phenomenon is particularly evident in the case of Mars, which underwent a significant magnetic reversal in its past.

Mars: The Lost World of Our Solar System

Mars, once a fertile planet with an active internal dynamical system, lost its rotary dynamics due to a massive magnetic reversal. Its matured outer mantle was propelled into space, forming Phobos and Deimos, the moons of Mars. The rest of the outer crust was crushed and propelled into the asteroid belt around the Sun, explained by the presence of electromagnetic radiation and fragmented rocky materials observed on its surface.

The Case of Venus and Potential for Life

While Mars has lost its internal dynamism, Venus is in the process of becoming a potential environment for life, albeit in a different form. It is still a monopole, capable of absorbing electrons from the solar wind directly into its inner core, a process that requires the activation of a Spherical Vortex. Once this activation occurs, Venus may be able to start its electromagnetic spinning, potentially supporting life.

Conclusion

The gas giants in our solar system, particularly Jupiter and Saturn, possess solid cores that are essential to their existence. Understanding these cores and the processes that govern their growth provides valuable insights into the formation and evolution of planets in our solar system and beyond. Future studies may reveal more about the conditions necessary for life to thrive, even on planets that are vastly different from our own.