A Holographic Principle for Non-Relativistic Quantum Mechanics
- URL: http://arxiv.org/abs/2301.04180v1
- Date: Tue, 10 Jan 2023 19:21:26 GMT
- Title: A Holographic Principle for Non-Relativistic Quantum Mechanics
- Authors: Russell B. Thompson
- Abstract summary: The isomorphism allows quantum particles in space-time to be represented as classical one-dimensional threads embedded in a five dimensional thermal-space-time.
If the Feynman dimension is considered to be real, there is a duality between classical threads in five dimensions and quantum particles in four dimensions.
intuitive explanations are given for quantum phenomena including the uncertainty principle, tunnelling, geometric phase, and interference effects.
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- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The quantum-classical isomorphism for self-consistent field theory, which
allows quantum particles in space-time to be represented as classical
one-dimensional threads embedded in a five dimensional thermal-space-time, is
summarized and used to explain a selection of quantum phenomena. Introduced by
Feynman, and used for modern quantum simulations, the isomorphism, when phrased
in a field-theoretic way, has been shown to be the same as quantum density
functional theory, the theorems of which guarantee equivalent predictions with
non-relativistic quantum mechanics. If the Feynman dimension is considered to
be real, there is a duality between classical threads in five dimensions and
quantum particles in four dimensions. Using the 5D picture, intuitive
explanations are given for quantum phenomena including the uncertainty
principle, tunnelling, geometric phase, and interference effects. Advantages of
the 5D picture are presented, which include fewer postulates, no measurement
problem, and the need for only classical concepts in the higher dimensional
space. Limitations of the approach such as the interpretation of entanglement
and spin are discussed.
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