The Creation Particle Temporal Expansion Universe theory.

Title:

Temporal Discontinuity and the AZ-Mass Hypothesis:
A Speculative Framework for Dark Matter and Accelerating Expansion

Authors:
Dr. David Kawasaki (Lead Author), Ludlow Research Institute
Tommy Russo, Senior Systems Analyst, Pathfinder Division
Pastor John McGary, Independent Theological Consultant & Radio Astronomer

Abstract
This exploratory paper presents a speculative cosmological hypothesis centered on the idea of an origin-state matter construct referred to as AZ-mass—a unified singularity outside of time and space that existed prior to the Big Bang. We propose that this timeless, all-force singularity initiated a causal disturbance that set expansion into motion. This movement before the creation of time may help explain the accelerating expansion of the universe, traditionally attributed to dark energy. We also explore whether gravitational anomalies (currently labeled as “dark matter”) could represent weak points or semi-permeable boundaries in the time-space continuum where gravity from the AZ-mass origin leaks through. Lastly, we address the paradox of anomalously old galaxies by hypothesizing that temporal rates vary near the edge of universal time, leading to accelerated aging in observable structures at great cosmological distances.

1. Introduction

In the standard model of cosmology, the universe began from a singularity—a point of infinite density and energy—expanding into what we now observe as spacetime. However, this model leaves unanswered the origin and mechanism of this singularity. What, if anything, preceded the Big Bang? What initiated the expansion? And why does that expansion appear to be accelerating?

We propose that prior to spacetime, there existed a state of absolute unification—of energy, matter, and all four fundamental forces—outside of time. We call this pre-Big Bang construct the AZ-mass (Absolute Zero-time Mass), and it forms the theoretical cornerstone of this speculative framework.

2. The AZ-Mass and the Hypothesis of Timeless Movement

We begin with the assumption that time began at the moment of the Big Bang. If AZ-mass existed before that, it did so in a state where causality, temporality, and relativity were meaningless. However, if this singularity experienced a directional shift—a “movement” or change in potential configuration—it would not be constrained by time. This movement may have caused the release of energy that created our expanding universe.

Such a disturbance would result in the continual expansion of spacetime as it “chases” this boundary of timelessness, never catching it. This might offer a novel conceptual origin for the cosmic inflation and its observed accelerating expansion—not as a “push” by dark energy, but as a “pull” toward an unreachable temporal edge.

3. Weak Points in the Continuum: A New Interpretation of Dark Matter

Dark matter is inferred from gravitational effects that cannot be explained by observable matter alone. However, direct detection has remained elusive. If we consider that AZ-mass exists outside of spacetime but still exerts gravitational influence, then localized stress points in the temporal fabric—where time is thin or malformed—could allow “gravity leaks” into our spacetime.

These distortions, or gravity seep zones, might cluster around galactic structures, behaving gravitationally like dark matter but eluding particle detection because they are not material entities within our time-bound reference frame. This reframes dark matter not as exotic particles but as spacetime discontinuities.

4. Temporal Dilation and Ancient Galaxies

Recent observations of early-universe galaxies suggest structures more developed than current models allow for their age. In our framework, this is addressed by proposing that time flows differently at varying distances from the origin. Close to the AZ-mass boundary—i.e., farther back in the universe’s temporal “depth”—the local passage of time may be significantly accelerated from our reference frame.

Thus, galaxies formed near the temporal edge might evolve and age faster in their own context, appearing anomalously old to us. This hypothesis challenges the assumption of a universal and constant temporal flow, inviting reinterpretation of redshift and cosmic distance indicators.

5. Black Holes, Information, and the Time-Independent Frontier

In some modern theories, black holes may serve as bridges or interfaces between time-bound and time-independent realms. Hawking radiation, Bekenstein entropy, and the information paradox suggest that black holes do more than absorb—they store, transform, or perhaps even transmit.

If AZ-mass exists outside of time and black holes connect to that realm, then they may function like cosmic “hard drives,” preserving information about the universe or communicating with the AZ-origin. The boundaries of a black hole might mirror those of the universe itself: a liminal surface where time ceases to function predictably.

6. Discussion

This model, though speculative, offers a unifying lens through which multiple phenomena may be interpreted:

• Accelerating expansion becomes a gravitational chase toward a moving time-edge.

• Dark matter is recast as gravitational leakage from outside of time.

• Early galaxy formation is explained by temporal gradients within spacetime.

• Black holes may serve as portals or reflections of AZ-mass properties.

While this theory lacks falsifiability in its current form, it could inspire new interpretations of data from the James Webb Space Telescope, LIGO-VIRGO observatories, and gravitational lensing studies.

7. Conclusion

The AZ-mass hypothesis introduces a pre-physical, timeless singularity as both origin and gravitational attractor. By framing cosmological expansion, dark matter effects, and temporal anomalies as symptoms of our proximity to this timeless frontier, we offer a novel paradigm—one not yet testable, but rich in conceptual potential.

We encourage physicists, cosmologists, and theoretical mathematicians to consider this framework not as dogma, but as an open model for further development.

8. Bibliography The

• Bekenstein, Jacob D. Black Holes and Entropy. Physical Review D, 1973.

• Hawking, Stephen. A Brief History of Time. Bantam Books, 1988.

• Penrose, Roger. Cycles of Time: An Extraordinary New View of the Universe. Alfred A. Knopf, 2010.

• Tegmark, Max. Our Mathematical Universe. Vintage, 2014.

• Webb, James. Spectral Observations of High-Redshift Galaxies. NASA Goddard, 2023.

• Verlinde, Erik. On the Origin of Gravity and the Laws of Newton. arXiv:1001.0785 [hep-th], 2010.

Author Note:
This paper is speculative in nature and is presented as part of the Ludlow Research Institute’s initiative to explore unorthodox cosmological models. It is not intended as a definitive statement of fact but as a theoretical stimulus for further exploration.