Reframing Gravity with Wave Mechanics
1. What is Acoustic Gravitic Theory in simple terms?
It’s a new way to think about gravity. Instead of being a mysterious pull from mass (like Newton said) or a warp in spacetime (like Einstein said), gravity is a push from pressure waves. These waves come from the Sun, travel through space and the atmosphere, and press down on objects through oscillations—kind of like invisible pressure fields. It’s like living inside a giant speaker that’s always on, but in ultra-low frequencies.
2. Where do these pressure waves come from?
The Sun is constantly sending out electromagnetic and magnetosonic waves—especially in ultra-low-frequency (ULF) and extremely low-frequency (ELF) bands. These waves enter Earth’s system mostly through the poles and stir up vibrations in Earth’s molten core. That seismic energy travels upward and becomes infrasound in the atmosphere. That’s the wave field pushing everything down.
3. What makes objects fall if there’s no “pull”?
Gravity is the result of seismic-acoustic waves generated inside the Earth by solar oscillations. These waves rise from below and convert into infrasound in the atmosphere, forming a vertical pressure field. Because solid objects can’t move in sync with these low-frequency waves, a pressure imbalance builds above them, pushing them downward. The waves come from within—but the force is felt from above. This mismatch in response is called an impedance mismatch, and it causes pressure to build on the top of objects.
4. Is this just about gravity on Earth, or does it apply to space too?
It works in both places. In space, planets don’t orbit because of mass-based gravity. Instead, they find stable “parking spots” in wave troughs—think of ripples spreading out from the Sun. These troughs are formed by standing magnetosonic waves in the plasma of space. Planets are “locked in” to these stable zones based on wave alignment, not mass.
5. Why haven’t we heard about this before?
Mainstream physics has focused on spacetime and particles for over a century. But many of the tools to measure and simulate large-scale wave fields across space and atmosphere are fairly recent. This theory builds on work by respected scientists like Hannes Alfvén (plasma physics), Eugene Parker (solar wind), Irving Langmuir (wave oscillations in plasma), and Vilhelm Bjerknes (acoustic pressure forces)—it just connects their discoveries into one unified picture.
6. What about the inverse-square law? Doesn’t that prove Newton right?
Acoustic Gravitic Theory explains the inverse-square law, but differently. Pressure waves spread out as they travel—so their strength naturally weakens with distance, like the intensity of sound dropping the farther you are from the source. That’s why gravity appears to follow a 1/r² rule—it’s just how wave pressure falls off in space.
7. Can this be tested? Has it been?
Yes—and parts of it already have been. The theory predicts infrasound changes during solar events, which can be measured using barometers and infrasound arrays. It also suggests microgravity changes detectable with gravimeters. There’s even a proposed lab test to levitate a 1-gram object using controlled acoustic phase cancellation. The required pressure for this is about 6.25 Pascals—a level we can reach with existing tech.
8. Does this mean Einstein was wrong?
Einstein wasn’t wrong—his math still describes motion well—but the cause behind what he described may have been misinterpreted. Instead of curvature in an abstract space, the actual cause might be pressure waves in a real medium. So, instead of scrapping his work, Acoustic Gravitic Theory gives it a physical foundation rooted in observable, testable mechanics.
9. How does this theory explain black holes and time dilation?
Black holes are seen as intense plasma pinches, not spacetime singularities. Time dilation, meanwhile, is explained as a shift in oscillatory frequency caused by pressure fields—atomic clocks slow down not because time bends, but because the resonant pressure environment changes.
10. So what does this theory change for us?
Everything—from how we think about propulsion, gravity control, and space travel, to how we interpret cosmological data. It means gravity isn’t some unreachable mystery—it’s a force we can interact with, manipulate, and possibly reverse. It’s the beginning of a new wave in science—literally.