Introducing Vacuum Synchronization Theory
Figure: Conceptual illustration of vacuum synchronization — phase oscillations aligning across nested fields.
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Why do clocks slow down near massive objects? Why does light shift to red near gravity wells? What exactly are gravitational waves? Vacuum Synchronization Theory offers a new answer: space is not just curved — it’s actively resynchronizing.
In this view, mass draws energy from the vacuum field to sustain its internal oscillations. This energy extraction causes the surrounding vacuum to lose frequency — not as curvature, but as phase depletion. The result? A slower ticking vacuum field, and with it, a fresh explanation for redshift, time dilation, and gravitational waves.
📘 Part 1: The Maths of Quantum Synchronisation
We begin with a generalized field equation. Unlike Einstein’s geometric curvature model, this equation expresses gravity as a dynamic synchronization process in a nested quantum field structure.
📘 Part 2: Gravitational Redshift from Vacuum Phase Depletion
How does this theory explain gravitational redshift? By showing that photons emitted near mass originate in a slower vacuum field, making their frequency appear redshifted when viewed from farther away. It matches standard GR results — but comes from a field-based mechanism.
📘 Part 3: Gravitational Waves as Vacuum Phase Pulses
When a massive object moves suddenly, it causes a temporary phase mismatch in the surrounding vacuum. The correction travels outward — not as pure spacetime ripple, but as a phase pulse. These vacuum pulses explain gravitational waves as synchronization shockwaves.
📣 Next: Predictions and Experimental Tests
Future work will lay out testable predictions, including transient redshift anomalies, clock sync shifts during mass motion, and observable delays in vacuum field adjustment.
This theory is open for review, discussion, and collaboration. If you are a physicist, engineer, or interested thinker — feel free to join the conversation.
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