Oscillating Spacetime The Foundation of the Universe.pdf

Oscillating Spacetime: The Foundation of the Universe
John A. Macken
Santa Rosa, California, USA
Journal of Modern Physics - June 2024

Unification of forces, Electron model, Cosmological
constant problem, Foundation of physics, Aether.
Keywords:
Exploring the intricate interplay of quantum mechanics and relativity, Oscillating
Spacetime: The Foundation of the Universe unveils the graceful movements of the
cosmos, exposing the underlying essence of existence.

The slides present a unique perspective on spacetime, portraying it as a quantum mechanical sonic medium composed of
tiny oscillations at the Planck frequency and length. These oscillations give rise to the fundamental constants of spacetime,
such as the speed of light (c), the gravitational constant (G), and the reduced Planck constant (ħ). It is proposed that these
oscillations, which create a vibrating spacetime, serve as the singular universal field responsible for generating and unifying
everything in the universe.
The 17 fields of quantum field theory are depicted as lower frequency resonances of this oscillating
spacetime.
In this model, the electron is envisioned as a rotating soliton wave within this medium. Despite its wave-particle
duality, the electron is fundamentally a quantized wave. This soliton wave can vary in size, shrinking smaller than a
proton during high-energy collisions or expanding to the larger volume of an atom's orbital wave function. When
detected, the electron undergoes a superluminal collapse to a smaller wave size, exhibiting particle-like properties.

The proposed wave-based electron model has been tested and found to align with the approximate energy, de Broglie
wave properties, and undetectable volume of an electron. Importantly, this model also provides an explanation for the
generation of electrostatic and gravitational forces experienced by an electron. The gravitational forces are derived from the
nonlinearity of the medium, while the equations become simplified by modeling these forces as distortions of soliton waves.
This reveals a direct relationship between the two forces, where the gravitational force between two Planck masses is
equal to the electrostatic force between two Planck charges, with both forces magnitudes equating to ħc/r^2.
This exploration into oscillating spacetime and its connection to the Lorentz transformation opens up new avenues for
understanding the fundamental workings of the universe. Delve into the slides to further explore this groundbreaking
theory.
Reference:- Oscillating Spacetime: The Foundation of the Universe

The study discussed in this article started by recognizing a link between the characteristics of light trapped inside a laser
and the physical traits of particles. The light bouncing back and forth between the laser's mirrors is constrained to follow
the mirrors' perspective. This confined light creates standing waves that display 5 properties similar to those of
fundamental particles. For instance, when observed from a moving perspective, the two-way light within a laser shows a
wave property similar to the de Broglie waves of a moving electron. The standing waves in a moving laser also experience
relativistic length contraction, time dilation, and energy increase. Additionally, the confined light waves possess inertia (rest
mass). If the laser is accelerated, the light inside exerts unequal pressure on the mirrors, creating a force that opposes
acceleration. These effects will be elaborated on in Sections 7 and 8 of the article (Oscillating Spacetime). These findings
demonstrate that when light is confined to a specific frame of reference, it displays particle-like characteristics.
The author have multiple patents related to lasers and optics, which led me to consider creating a wave-based model of an
electron that incorporates both relativistic and quantum mechanical properties. For instance, a rotating soliton wave could
represent an electron with a specific frame of reference, embodying these important properties. However, developing this
model would necessitate a wave propagating medium that surpasses the concept of aether. This medium would need to be
the fundamental basis of everything in the universe, generating all fermions and forces through waves. The idea was to
unify the 17 separate fields of the standard model into one universal field propagated by waves, creating a comprehensive
model of the universe. This wave propagating medium would need to possess extreme properties, capable of supporting
highly energetic waves while remaining undetectable to us.

Quantum field theory suggests that the quantum vacuum is a field made up of harmonic oscillations with zero-point energy.
If we consider the Planck frequency, the energy density of this field matches the Planck energy density. However,
observations show that the universe aligns more with the flat Lambda-CDM model, indicating a much lower average
energy density. This significant discrepancy, known as the cosmological constant problem, has puzzled physicists for years.
While many try to dismiss the discrepancy, I see it as a potential foundation for a wave-based model of the universe.
Instead of explaining it away, I aim to prove the existence of this quantum mechanical energy density.
John Archibald Wheeler provided support for the idea that the quantum vacuum has a property with a mathematical value
of 10113 J/m3. He studied the uncertainty principle and vacuum zero-point energy, and concluded that these effects could
be explained if the "geometry of spacetime fluctuates". According to his findings, 4-dimensional spacetime is made up of
vacuum oscillations at the Planck frequency (ωp) and Planck length (Lp). This concept of the quantum vacuum has become
the basis for the model of the universe proposed here. In Section 4, we will analyze this description of spacetime, which
mathematically corresponds to a Planck energy density of 10113 J/m3. However, this energy density only becomes
observable when angular momentum is added, essentially creating an excitation. By introducing a unit of quantized angular
momentum into this medium, a rotating soliton wave can be formed. This wave would have a specific frame of reference
and could potentially serve as a model for an electron. Wheeler's model of spacetime is often referred to as "quantum
foam" or "spacetime foam". However, in this article, we will use the term "oscillating spacetime" to accurately describe the
nature of the spacetime model under discussion.

Wheeler’s concept of spacetime is discussed in the last chapter of the authoritative
reference Wheeler coauthored. This reference states, “No point is more central than
this: space is not empty. It is the seat of the most violent physics…. The density
of field fluctuation energy in the vacuum ∿ 1094 g/cm3 (∿10113 J/m3) argues that
elementary particles represent a percentage-wise almost completely negligible change
in the locally violent conditions that characterize the vacuum…” The structure of these
fluctuations is described as: “The geometry of space is subject to quantum fluctuations
in metric coefficients of the order of: Planck length/length extension of the region under study” .
Many articles have also been about spacetime foam and related subjects. None
of those articles give details suggesting that spacetime foam is the fundamental building
block of everything in the universe
The article start with a discussion of the sonic properties of oscillating
spacetime consisting of Planck length oscillations at Planck frequency. These properties
include the calculation of its propagation speed, impedance and bulk modulus. A wavebased model of an electron is
developed from this medium. Tests of this electron model
show it achieves an electron’s energy, de Broglie waves, and spin. This model
unexpectantly is found to also generate an electron’s electrostatic and gravitational
forces. Treating these forces as wave interactions in oscillating spacetime results in
proof that these forces are closely related. The wave-based model of the universe also
makes several predictions about gravitational relationships, photons, entanglement,
and the Big Bang. The conclusion is that this is a successful and useful model of the
universe.