- Mar 25, 2025
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1. Starting Premise
-Our Current understanding of dark matter is limited to its observed gravitational effects, with no direct evidence of interaction with ordinary matter or light.
Are we looking at Dark Matter wrong? What if Dark Matter is not matter as traditionally defined but instead consists of constant, primordial vibrational waves originating from the Big Bang.
2. Connection to the Big Bang
- The immense energy released during the Big Bang could have generated vibrational waves that still permeate the universe.
- These waves could act as "memories" of the Big Bang, influencing the expansion and structure of the universe over time.
3. Role of Vibrational Waves
- Such waves could exert force, interacting indirectly with ordinary matter and creating observable distortions.
- Constant and consistent waves might influence captured mass, leading to regular patterns in cosmic structures.
Vibrational waves inherently carry energy and momentum. If these dark matter waves propagate through space, they could exert subtle but consistent forces on masses they interact with, "capturing" them in stable positions or motions. This might resemble the way sound waves can trap particles in acoustic levitation experiments.
4. Observable Phenomena
- Patterns in spiral galaxies, similarities between atomic and cosmic structures, and gravitational effects attributed to dark matter could reflect wave-matter interactions.
- Vibrational waves may also contribute to the universe's accelerating expansion, potentially offering an alternative explanation to dark energy.
Over time, the consistent wave interactions might lead to repeating, cyclical behaviors in the captured mass. For instance, orbital paths, rotations, or oscillations might exhibit patterns shaped by the wave properties—frequency, amplitude, and wavelength.
If dark matter waves influence mass in this way, their signature could manifest in the large-scale structures of the universe, like the arrangement of galaxies or the rotational curves within them. These patterns could even provide a new framework for interpreting phenomena currently attributed to gravitational effects alone.
5. Testing the Theory
- Investigate large-scale patterns in galaxy formation and distribution for evidence of regular wave-like behavior.
- Analyze existing datasets (e.g., Cosmic Microwave Background radiation) for potential signatures of primordial vibrational waves.
- Develop mathematical models to simulate interactions between vibrational waves and matter, predicting observable effects.
-Our Current understanding of dark matter is limited to its observed gravitational effects, with no direct evidence of interaction with ordinary matter or light.
Are we looking at Dark Matter wrong? What if Dark Matter is not matter as traditionally defined but instead consists of constant, primordial vibrational waves originating from the Big Bang.
2. Connection to the Big Bang
- The immense energy released during the Big Bang could have generated vibrational waves that still permeate the universe.
- These waves could act as "memories" of the Big Bang, influencing the expansion and structure of the universe over time.
3. Role of Vibrational Waves
- Such waves could exert force, interacting indirectly with ordinary matter and creating observable distortions.
- Constant and consistent waves might influence captured mass, leading to regular patterns in cosmic structures.
Vibrational waves inherently carry energy and momentum. If these dark matter waves propagate through space, they could exert subtle but consistent forces on masses they interact with, "capturing" them in stable positions or motions. This might resemble the way sound waves can trap particles in acoustic levitation experiments.
4. Observable Phenomena
- Patterns in spiral galaxies, similarities between atomic and cosmic structures, and gravitational effects attributed to dark matter could reflect wave-matter interactions.
- Vibrational waves may also contribute to the universe's accelerating expansion, potentially offering an alternative explanation to dark energy.
Over time, the consistent wave interactions might lead to repeating, cyclical behaviors in the captured mass. For instance, orbital paths, rotations, or oscillations might exhibit patterns shaped by the wave properties—frequency, amplitude, and wavelength.
If dark matter waves influence mass in this way, their signature could manifest in the large-scale structures of the universe, like the arrangement of galaxies or the rotational curves within them. These patterns could even provide a new framework for interpreting phenomena currently attributed to gravitational effects alone.
5. Testing the Theory
- Investigate large-scale patterns in galaxy formation and distribution for evidence of regular wave-like behavior.
- Analyze existing datasets (e.g., Cosmic Microwave Background radiation) for potential signatures of primordial vibrational waves.
- Develop mathematical models to simulate interactions between vibrational waves and matter, predicting observable effects.
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