Time Compression Theory

Compressed time structure around a mass, with decreasing energy as the distance from the mass is increased.

In theoretical physics, the time compression theory is a modern concept where layers of time compression and energy bands arise in the presence of a mass. The theory presents an alternative to the current gravitational model within General Relativity and, in the absence of space, proves time is an electromagnetic wave.^[1].

Background[edit]

The time compression theory's origin is largely the product of the disparity between general relativity and quantum mechanics. The Time Compression Theory states that the incompleteness of general relativity led scientists down an incorrect path, leaving physicists desperately searching for a non-existent connection between the very large and the very small^[2].

The time compression theory disregards the concept of distances, velocities and accelerations in space claiming they are "merely an illusion of the mind"^[1]. Man's creation of spacial dimensions is replaced with time dimensions providing a model based solely on time and energy.

Underlying Principles[edit]

Time cone concept - distances to objects are defined in time, measured from an observer's present.

Every observer is in the present. The time compression theory uses the concept of a time cone where the observer and only the observer is situated at the tip of their unique cone. Every event in the universe is situated within the time cone in the observer’s past. This time distance is defined as the length of time that light takes to traverse from the event to the observer.

In undistorted time, every object progresses along its timeline (from the past and into the future) at the rate of time free fall, T_f. A stationary object in compressed time moves through time slower than T_f, proportionally to the gravitational attraction. An object closer to Earth is in an area of denser time. The increase in time compression is proportional to the gravitational attraction towards the centre of Earth. Therefore, the closer an object is to Earth, the slower it moves through time.

Applications[edit]

Black Holes (Black Spheres)[edit]

The time compression structure around a black hole eliminates the requirement of a singularity and results in an extremely dense mass, named the ‘black sphere’. The radius at which an object's kinetic energy can not be increased, in other words, when the required velocity equals the speed of light, is known as the event horizon. Beyond this point, no object’s centre of mass has the ability to travel at time freefall. This proves that every object, including light, will travel towards the centre of the black hole, whilst within the event horizon. This region therefore appears black. Due to the elimination of a singularity, the time compression theory defines a black hole as a black sphere with the understanding there is a highly dense mass situated at its centre. The extremity of the compressed time layers causes time to slow down so much, that light takes billions of years to reach the mass inside^[3]

References[edit]

↑ ^1.0 ^1.1 Innes, Daniel. "Time Compression Theory - Establishing a causality link between electromagnetism and gravity".
↑ Time Compression Theory (2018-09-27), Time Compression Theory (unifying gravity and electromagnetism), retrieved 2018-11-29
↑ Innes, Daniel. "Time Compression Theory - Black Holes".

Template:Quantum Gravity

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[Innes-1] 1.0 ^1.1 Innes, Daniel. "Time Compression Theory - Establishing a causality link between electromagnetism and gravity".

[2] Time Compression Theory (2018-09-27), Time Compression Theory (unifying gravity and electromagnetism), retrieved 2018-11-29

[3] Innes, Daniel. "Time Compression Theory - Black Holes".

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