Emergent Universe from Many Unreal World Interpretation
International Journal of Applied Mathematics and Theoretical Physics
Volume 6, Issue 2, June 2020, Pages: 14-18
Received: Apr. 11, 2020;
Accepted: May 26, 2020;
Published: Jun. 15, 2020
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Bhushan Bhoja Poojary, Bachelor of Science Physics, NIMS University, Jaipur, Rajasthan, India
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There are multiple interpretations of quantum mechanics, 2 most famous interpretations are Copenhagen interpretation and many world interpretations. Copenhagen interpretation fails to explain the mechanism behind wave function collapse and many world interpretations avoid collapse by adding infinite branching worlds. Goal of this paper is to provide alternate interpretations which explains mechanism behind collapse using finite pre-existent unreal worlds. All quantum weirdness can be narrowed down to few postulates, if we consider every particle has a dedicated address in event horizon, every address has its own dedicated spacetime fabric, particles will have its projected shadows on other space time fabric and whenever there is interaction between true particle and other shadow particle, new address is assigned for both interacting particles and instantaneously all projected shadow becomes void. We perceive universe from collapse perspective only when particles collapse and new address are assigned, thus giving an illusion that we live in one universe but its result of interaction of multiple worlds. From new postulates we were able to explain how one of the entangled photons can decides other photons path in Wheeler's delayed choice experiment and thus helps us to removes problematic retro causality speculation to explain the phenomenon observed in this experiment.
Quantum Mechanics Interpretation, Wave Function Collapse, Superposition, Wheeler's Delayed Choice Experiment
To cite this article
Bhushan Bhoja Poojary,
Emergent Universe from Many Unreal World Interpretation, International Journal of Applied Mathematics and Theoretical Physics.
Vol. 6, No. 2,
2020, pp. 14-18.
Copyright © 2020 Authors retain the copyright of this article.
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