Gravity doesn't begin instantly.

   Gravity doesn't begin instantly.

Gravity, or gravitational interaction, is one of the most powerful and dominating effects of what we know. We can describe gravitational interaction as the process where two particles or objects form a bridge and that bridge or energy tunnel pulls objects together. The size and density of the object determine its gravitational field. 

We can see that large and dense objects have strong gravitational fields. That thing causes an idea that quantum low pressure in the middle of the large particles causes a situation where quantum fields start to travel in the middle of the particle.

The outcoming gravitational radiation causes a thing called a gravity field. The reason why gravitational interaction doesn't begin immediately is that the tunnel where gravitation interacts. This tunnel is the thing that causes gravitational interaction between dark matter and visible matter. The gravitational tunnel must form before gravitational interaction can begin. 

The question is where that gravitational radiation comes from. Of course, we can say that it comes from a particle called graviton. And maybe graviton is the thing that forms interaction between gluon and quark. In that model, graviton could be like a small black hole between gluon and quark. 

In that model, large and dense objects can cover the gravitational nucleus. That thing denies outcoming radiation impact to the gravitational center. This causes situations where gravitational waves can travel longer than in the case of small and non-dense objects. There is no other limit for gravitational effect's distance than other gravitational waves. A large and dense object sends gravitational waves with stronger power than a low-mass object. 

Impacting gravity waves causes the situation that there are forming standing waves in that radiation. Those standing waves adjust gravitational waves into another frequency. Those other four frequencies and wavelengths are other fundamental interactions. 

The reason why gravitational interaction is so weak is in wavelength. But it interacts in long distances is that other interactions. That is wave movement with other wavelengths covering gravitational waves under them. 

Normally we use copper or other metallic antennas that are receiving electromagnetic wave movement. The gravitational interaction has so a short wavelength that it cannot resonate with those atoms in a large area that the resonance is detectable. 

All four fundamental forces are the quantum fields. And if there is only one force in the universe that could explain gravitation like this. When objects send gravitational radiation from the gravitational center. That gravitational interaction pushes other gravitational waves away. Then gravitational waves try to push that outcoming gravitational radiation back in the gravitational center. 

To force the gravitational radiation back into the gravitational center requires. It reaches a higher energy level than gravitational radiation that comes from the gravitational center. That outcoming radiation must store enough energy to make that thing. 

The outcoming gravitational waves that travel into the gravitational center form standing waves. And the height of those standing waves must be high enough. That they can push gravitational radiation back in. So the idea is this. Gravity is the base wave movement. Impacting gravitational waves form higher waves that are weak nuclear interaction, strong nuclear interaction, and electromagnetism. The difference between those forces is only wavelength. 

The gravitational interaction is based on the idea that when somewhere is an electromagnetic shadow. That means that electromagnetic fields start to travel to fill that area. The interesting thing is that gravitation seems to interact oppositely with other quantum fields or fundamental interactions.

The gravitational radiation is one of the biggest mysteries in the universe. That radiation pushes all other quantum fields away from the gravitational center. The thing that causes the pulling effect is the case that quantum fields impact with those gravitational waves. 

https://bigthink.com/starts-with-a-bang/gravity-doesnt-happen-instantly/