Astrophysical Proposal: Investigating Hyperspherical Expansion through Gravitational Waves

"Testing Hyperspherical Time Dynamics and Black Hole-Induced Spacetime Expansion via Gravitational Wave Observations"

This study explores the hypothesis that black hole spin and mass-energy transfer can contribute to spacetime formation, potentially linking existing universes to newly emerging structures. Using gravitational wave data from LIGO and VIRGO, we aim to identify frame-dragging distortions, unexpected energy redistribution, and anomalous wave decay patterns that may support hyperspherical evolution.
1. Theoretical Framework

- Time behaves as a radial dimension in a hypersphere, meaning curvature influences perceived time progression.
- Extreme black hole spin may alter local spacetime structure, potentially initiating new spacetime formation.

- Kerr metric analysis suggests frame-dragging could distort wave propagation, producing signals inconsistent with classical expansion models.
- Could extreme spin create hyperspherical distortions that hint at spacetime bifurcation?

- If black holes act as spacetime feeders, conservation laws must account for energy moving into new structures.
- Do gravitational waves carry signatures of energy leakage, suggesting black hole interactions beyond classical physics?
2. Observational Strategy

- GW190521 → One of the highest-spin mergers detected. Does the waveform indicate unexpected hyperspherical distortions?
- Extreme Kerr black holes → Look for post-merger anomalies where spacetime structure might hint at energy transfer mechanisms.

- LIGO/VIRGO datasets → Direct gravitational wave signals.
- Electromagnetic counterparts → Can light echoes from mergers correlate with wave distortions, revealing time dilation effects?
3. Expected Outcomes





- Reinterpreting cosmic expansion: If hyperspherical time dynamics explain wave behavior, dark energy assumptions may need revision.
- New pathways for spacetime formation: If black holes generate new universes, this changes how we view singularities and cosmic birth.
4. Next Steps

- Strengthen Kerr-black hole spin equations to explicitly capture hyperspherical distortions.
- Introduce constraints that account for multi-universe energy transfer.

- Compare LIGO wave signals to expected hyperspherical distortions.
- Engage astrophysical researchers for high-spin black hole post-merger tracking.
Astrophysical Proposal: Investigating Hyperspherical Expansion and Black Hole-Induced Spacetime Formation via Gravitational Waves
Title:
"Testing Hyperspherical Time Dynamics and Black Hole-Induced Spacetime Expansion via Gravitational Wave Observations"
Abstract:
This study explores the hypothesis that black hole spin and mass-energy transfer contribute to spacetime formation, potentially linking existing universes to newly emerging structures. Using gravitational wave data from LIGO and VIRGO, we aim to identify frame-dragging distortions, unexpected energy redistribution, and anomalous wave decay patterns that may support hyperspherical evolution.
Additionally, we propose that our own universe may be the result of a black hole in another universe, feeding spacetime into our cosmic structure. If black holes serve as umbilical connections to new universes, gravitational waves might carry signatures of spacetime transfer, offering a unique test for this theory.
1. Theoretical Framework
Hyperspherical Cosmology and Radial Time Evolution
- Time behaves radially in a hypersphere, meaning curvature influences perceived time progression.
- Extreme black hole spin may alter local spacetime structure, potentially initiating new universe formation.
Black Hole Spin as a Universe-Seeding Mechanism
- Kerr metric analysis suggests frame-dragging could distort wave propagation, producing signals inconsistent with classical expansion models.
- Could extreme spin rupture spacetime, linking existing universes to newly formed ones?
- If black holes feed spacetime into a new region, this could explain why our universe appears to emerge from singularity-like conditions.
Our Universe as the Product of an External Black Hole
- If black holes act as spacetime generators, then our universe might originate from an external high-spin black hole in another cosmos.
- This offers a natural mechanism for energy transfer across cosmic structures.
- If true, remnants of this birth event might be detectable in early universe gravitational wave signatures.
2. Observational Strategy
Target Gravitational Wave Events
- GW190521 → One of the highest-spin mergers detected. Could it show unexpected hyperspherical distortions?
- Extreme Kerr black holes → Look for post-merger anomalies where spacetime structure might hint at energy transfer mechanisms.
- Primordial Gravitational Waves → If our universe emerged from a black hole, early gravitational wave remnants might reveal distortions in cosmic inflation.
Data Sources
- LIGO/VIRGO datasets → Direct gravitational wave signals.
- Cosmic Microwave Background (CMB) → Do temperature fluctuations hint at a hyperspherical birth origin?
- Electromagnetic counterparts to GW events → Can light echoes correlate with wave distortions, revealing time dilation effects?
3. Expected Outcomes
Hypothesis Testing




Potential Implications
- Reinterpreting cosmic expansion → If hyperspherical time dynamics explain wave behavior, dark energy assumptions may need revision.
- New pathways for spacetime formation → If black holes generate new universes, this changes how we view singularities and cosmic birth.
- Exploring a multiverse structure → If our universe originates from an external black hole, this hints at cosmic interconnectivity beyond standard models.
4. Next Steps

- Strengthen Kerr black hole spin equations to explicitly capture hyperspherical distortions.
- Introduce constraints that account for multi-universe energy transfer.

- Compare LIGO wave signals to expected hyperspherical distortions.
- Engage astrophysical researchers for high-spin black hole post-merger tracking.

- Investigate early universe gravitational wave remnants for signs of hyperspherical birth.
- Propose deep-field telescope observations that could detect redshift deviations consistent with hyperspherical evolution.
Final Thoughts
This proposal integrates everything we’ve explored—from time as a radial dimension in a hypersphere, to black hole-driven spacetime creation, to the fascinating possibility that our universe emerged from a black hole in another cosmic domain.
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