Multiverse
A universe might have the task of generating information and knowledge. Such a universe must possess a viable phase in order to gain life experience. Over the course of a period, it passes through several stages in which forces exert a specific effect. The viable quadrant lies within the first quarter of the period following its formation. There, its matter initially exists as dark energy and, as the universe expands, is enabled to couple. The matter capable of coupling – visible and dark matter – grows as the universe expands. At the same time, the gravitational force acts as an attractive force on the matter. Other quadrants of the current period possess repulsive gravitational forces, which make coupling between matter impossible.
If it is in the nature of the universe to create information, then it would be a contradiction for that information to simply disappear again after a certain time. Thus, through overlap with other universes, information could be transferred into alternative, ‘more information-friendly’ universes should its own universe lose its foundations. This occurs via the universal photon. The universal photon is the source of a universe’s existence. At the outset, it splits off a portion of its energy. The constants of nature are incorporated in the process. One universe differs from another solely in terms of the energy it contains and the phase it currently finds itself in.
This separation occurs in an extremely contracted state. In the state of a spin-0 pair with momentum 0 = Ppos – Pneg, a universe initially exists in a state of entanglement with the character of a photon. By its very nature, this entanglement also exists between the universe and the universal photon, so that the universal photon serves both as a medium of entanglement and as a shared quantum store. Information, phases and quantum states are interconnected across all universes. What happens in one universe is never completely separate from the others at the quantum-informational level.
Field-space-Mechanics thus describes a multiverse that not only exists, but in which all parts communicate with one another via the universal photon as a single, entangled quantum system.
Simulation:
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Landscape Problem
The landscape problem in string theory is that there are an extremely large number of possible vacua – often 10500 or more. Each vacuum can give rise to different physical constants, particle masses and even different gauge groups. As a result, the theory largely loses its predictive power – almost any observation can be explained by a suitable vacuum.
The FSM structurally avoids the landscape problem by making assumptions that are fundamentally different from those of string theory. The solution arises from several interrelated principles.
Fixed and small number of dimensions
- The FSM operates with exactly 7 dimensions (4 visible + 3 compact)
- no arbitrary number of extra dimensions and no wide range of Calabi-Yau manifolds. The three wave-field dimensions (D4 , D5 , D6) are fixed and oscillate dynamically.
Dynamic rather than static compactification
- Because of the oscillating dimensions, there are no static vacua in the string theory sense.
- The geometry is time-dependent. That alone drastically reduces the number of possible stable configurations.
Fixed initial symmetry and geometric refraction
- Fixed symmetry group SU(4).
- This breaks dynamically to SU(3) × U(1) via the phase angle β and oscillation.
- There are no arbitrary gauge groups or arbitrary symmetry breaking as in the string landscape.
Topological and geometric fixing of constants
- Number of generations = 3 (given by the number of turns n = 1, 2, 3)
- Fine-structure constant α ≈ 1/137
- Absence of anomalies due to Chern classes (c1 = 0, c3 = 0)
- Colour neutrality and transition through projection onto the visible spectrum
A multiverse with uniform constants as a ‘fingerprint’
- The universal photon is the origin of a universe.
- Any number of universes can come into being.
- Crucially, all these universes have the same fundamental constants. They differ only in size – depending on the energy input – and in the current stage of their periodic expansion.
- The universes are linked to one another via the universal photon.
- Because the universes pass through different phases of their oscillation, information or life can migrate from an ‘unfavourable’ universe to a life-friendly one (e.g. the first quarter-period).
- In the Planck regime, the universe does not collapse into a singularity, but into a pure wave state. When transformed back relativistically, this leads to a resonance with the universal photon.
Possible link to quantum information theory
In the FSM, the universal photon is the common origin of all universes. It connects these universes in a fundamental, non-local way.
The universal photon as a non-local channel of information:
- Entanglement (EPR) is equivalent to an Einstein–Rosen wormhole (ER).
- The universal photon can be interpreted as a shared entangled state that connects all universes, similar to a quantum network in which the individual universes represent nodes.
- In principle, information can be exchanged between universes without classical signals having to exceed the speed of light – quantum teleportation.
Phase-dependent multiverse and quantum information:
- This corresponds to the concept of quantum error correction from quantum information theory. Information is not lost, but is distributed redundantly across several ‘codes’ – in this case, universes in different phases.
- A universe in an ‘unfavourable’ phase can be regarded as a decoherent state, whilst another universe in a ‘favourable’ phase can be regarded as a coherent state that preserves information.
- The transmission of information between universes via the universal photon can be understood as a form of quantum teleportation or quantum communication over long distances (between universes).
Preservation of quantum information:
- Information is not lost, but is ‘outsourced’ to other universes that are in a more information-friendly phase.
- The universal photon acts as a shared quantum storage medium or as a medium of entanglement, similar to a quantum register in quantum information theory.
Spin-0 pair state and entanglement:
- This is a state of maximum entanglement.
- As long as the pair exists such that f < fmin, it is inseparable – a measurement on one part of the pair instantaneously affects the other part.
- This is a direct realisation of quantum entanglement on a cosmological scale.