In traditional astrophysics, the solar system is viewed as a relatively stable arrangement of planets orbiting the sun in elliptical paths due to gravitational forces. However, in this new perspective, which stems from the concept of space as a liquid-like medium rather than an empty vacuum, the dynamics of the solar system take on a far more fluid and spiral-bound interpretation.
The Sun’s Motion and the Spiral Effect
If the sun is not stationary but instead moves horizontally through this liquid-like space, then it must be creating a massive ripple or wave in its wake. Just as a large object in water generates a spiral current or whirlpool behind it, the sun’s motion could create a similar spiral wave structure in space. This wave would affect the positioning and motion of the orbiting planets.
In this scenario, the planets are not merely orbiting the sun due to its gravity. Instead, they are being carried and held in position by the swirling spiral current the sun generates as it moves. This model explains why the planets maintain their orbits so precisely, despite the constantly shifting backdrop of the expanding universe.
Gravity and the Spiral’s Stability
The conventional view of gravity assumes that massive objects warp space-time, pulling smaller objects toward them. But in a liquid space model, gravity could be a byproduct of spiral wave momentum. The downward or inclined nature of these waves would give the planets a stabilizing lift—somewhere between buoyancy and centrifugal force—keeping them aligned in stable orbits.
In this model, planets higher on the spiral wave receive slightly less force, while those on the lower troughs receive slightly more. This nuanced variation in force distribution could be responsible for the positioning of planets and their orbital speeds.
Preventing Doom by the Spiral
An important insight from this model is the survival mechanism it offers Earth. Earth’s delicate balance—its orbit, distance from the sun, and rotational speed—are what allow it to sustain life. If the expanding universe introduces even a slight change in distance or energy, Earth’s habitability could be compromised.
However, if Earth and other planets are held within a self-regulating spiral current in a liquid-like space, then the system may be more resilient than previously thought. The spiral wave acts like a safety net, ensuring that orbital paths adjust gradually and cohesively, rather than chaotically.
Liquid Space, Spiral Movement, and Asteroids
Even smaller bodies like asteroids, which seem too small to maintain inertia in a vacuum, continue moving because they too are caught in the liquid-like spiral flow. This also explains why these bodies are not randomly floating off into the cosmos; they are part of the same wave dynamics initiated by the sun’s movement.
The Nature of Spiral Movement
Finally, we must ask: is this liquid space stagnant or in constant motion? If it’s moving—spiraling outward from the singularity—then all cosmic bodies are part of a great unfolding wave. If it’s stagnant, then the energy released from the singularity, or central black hole, constantly energizes the spiral, like a fountain pumping water through a still pond.
This concept helps bridge ancient ideas and modern science, offering a fresh way to look at the cosmos—not as a static void, but as a dynamic, structured sea where everything swims in harmony with the spiral waves of creation.