Molecular construction in the relational quantum vacuum

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We conjecture that the quantum vacuum fluctuations operate through abstract mathematical relations of relations. Then we show how to construct a number of molecules from simple rules. Although this is an application of the Wolfram model, the conjecture itself is more general and therefore does not restrict to its rules.

https://doi.org/10.31219/osf.io/n5rzy

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 4, Article 271, 2022 [KQ]

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The qubit permutation semigroup

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We propose the equivalence between one Wolfram model and the qubit permutation semigroup.

https://doi.org/10.31219/osf.io/qkdxv

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 4, Article 270, 2022 [KP]

The inner structure of time

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Based on the idea that time is computation, we discuss one interpretation regarding the inner structure of time that explains quantum superposition.

https://doi.org/10.31219/osf.io/chmqy

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 4, Article 269, 2022 [KO]

The undecidable dynamics generate quantum probabilities

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We conjecture a new approach to quantum mechanics that, if confirmed, will explain the wave function from a fundamentally deeper level.

https://doi.org/10.31219/osf.io/hfc82

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 3, Article 242, 2021 [JM]

Time is a discrete dynamical system

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We conjecture that quantum vacuum operates its discrete dynamics in a superposition of a class of iterating functions such that each physical system operates within a distinct function.

https://doi.org/10.31219/osf.io/8f4yg

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 3, Article 238, 2021 [JI]

The logistics of quantum spacetime

[conjecture]

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We conjecture that quantum superposition is the result of the existence of different orbits in the logistic equation due to quantum interactions in spacetime.

https://doi.org/10.31219/osf.io/s2dnt

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 3, Article 236, 2021 [JG]

Is it possible to transfer quantum information non-locally?

[original insight]

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We discuss whether the quantum superposition of space, warp drive, and entanglement do transfer internal quantum information non-locally. In addition, the extra dimensions are conjectured to explain the aforementioned properties.

https://doi.org/10.31219/osf.io/ksjh9

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 2, Article 130, 2020 [FA]

Superposition of field oscillations

[microreview]

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We present a discussion on the superposition of oscillating fields.

https://doi.org/10.31219/osf.io/fuhd9

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 2, Article 129, 2020 [EZ]

Entanglement of the Uncertainty Principle

[original insight]

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We propose that position and momentum in the uncertainty principle are quantum entangled states.

https://doi.org/10.31219/osf.io/9jhwx

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 2, Article 127, 2020 [EX]

Entanglement of Superposition and Superposition of Entanglement

[conjecture]

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We consider that the superposition of space is given by the Bell states and that those states are in superposition themselves.

https://doi.org/10.31219/osf.io/zjdrm

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 2, Article 121, 2020 [ER]

Spacetime is a quantum computer

[conjecture]

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If spacetime is a quantum computer, then all physical systems are equivalent to quantum computational algorithms.

https://doi.org/10.31219/osf.io/rnckw

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 2, Article 111, 2020 [EH]

Genes are quantum computers

[conjecture]

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A sequence of logical arguments is presented in order to conclude that if biological cells are governed by quantum computational algorithms, then it is indeed possible to (re)program the genes’ states in a quantum computer.

https://doi.org/10.31219/osf.io/a7tbu

Open Mathematics Collaboration

Op. J. Math. Phys.
Volume 2, Article 109, 2020 [EF]