The falsification of the non-statistical interpretation of the uncertainty principle and the breakthrough of the statistical interpretation -- From the Uncertainty Principle to the Deterministic Rule

• URL: http://arxiv.org/abs/2103.03513v2
• Date: Mon, 15 Mar 2021 15:07:42 GMT
• Title: The falsification of the non-statistical interpretation of the uncertainty principle and the breakthrough of the statistical interpretation -- From the Uncertainty Principle to the Deterministic Rule
• Authors: De-Long Duan
• Abstract summary: This article traces the original derivation and the physical meaning of the Heisenberg uncertainty principle. It analyzes the Einstein photon-box thought-experiment, and studies the limits of the relationships under different action scenarios.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: It is well known that the problem of divergence in the physical interpretation of quantum mechanics originating from the uncertainty principle has not yet been resolved. Attempting to clear the constraints and confusion of this situation for the further development of quantum technology, this article traces the original derivation and the physical meaning of the Heisenberg uncertainty principle, analyzes the Einstein photon-box thought-experiment, and studies the limits of the relationships under different action scenarios. By analyzing the statistical distribution of quantum mechanical quantities, the result of the destruction of the non-statistical interpretation uncertainty relation in the electromagnetic interaction scenarios is obtained; through analyzing of the photon box thought experiment, the logical contradiction of Bohr's argument was discovered; by examining the set of interaction scenarios, a description method for determining the mechanical state of microscopic particles was put forward; according to the analysis of the hydrogen atom transition radiation process, basing on the principle of conservation of energy, the result of the lower limit of the uncertainty relation in the gravitational scene is much smaller than that in the existing electromagnetic scene is obtained, which mean the lower limit of uncertainty principle is broken. The research in this article has received an affirmative answer to Einstein's God does not play dice with the Universe. The research of this article is helpful to enhance the understanding of quantum physical phenomena in the microscopic world, and we hope it could render some theoretical support to investigating the physical basis of quantum technology.

Related papers

• A Theory of Quantum Jumps [44.99833362998488]
  We study fluorescence and the phenomenon of quantum jumps'' in idealized models of atoms coupled to the quantized electromagnetic field. Our results amount to a derivation of the fundamental randomness in the quantum-mechanical description of microscopic systems.
  arXiv  Detail & Related papers  (2024-04-16T11:00:46Z)
• Causality and a possible interpretation of quantum mechanics [2.7398542529968477]
  Based on quantum field theory, our work provides a framework that harmoniously integrates relativistic causality, quantum non-locality, and quantum measurement. We use reduced density matrices to represent the local information of the quantum state and show that the reduced density matrices cannot evolve superluminally. Unlike recent approaches that focus on causality by introducing new operators to describe detectors, we consider that everything--including detectors, environments, and humans--is composed of the same fundamental fields.
  arXiv  Detail & Related papers  (2024-02-08T07:07:22Z)
• Demonstrating Quantum Microscopic Reversibility Using Coherent States of Light [58.8645797643406]
  We propose and experimentally test a quantum generalization of the microscopic reversibility when a quantum system interacts with a heat bath. We verify that the quantum modification for the principle of microscopic reversibility is critical in the low-temperature limit.
  arXiv  Detail & Related papers  (2022-05-26T00:25:29Z)
• Coherence interpretation of the delayed-choice quantum eraser [12.507208769851653]
  We experimentally demonstrate the violation of the cause-effect relation using coherent photons for the quantum eraser. The observed quantum eraser is coherently interpreted to seek the origin of the cause-effect violation.
  arXiv  Detail & Related papers  (2022-02-13T00:28:22Z)
• Experimental study of quantum uncertainty from lack of information [3.901856932788151]
  The uncertainty in the classical domain comes from the lack of information about the exact state of the system. In this paper we investigate the issue experimentally by implementing the corresponding two-dimensional and three-dimensional guessing games. Our results confirm that within the guessing-game framework, the quantum uncertainty to a large extent relies on the fact that quantum information determining the key properties of the game is stored in the degrees of freedom that remain inaccessible to the guessing party.
  arXiv  Detail & Related papers  (2021-05-19T09:15:27Z)
• Quantum Causal Inference in the Presence of Hidden Common Causes: an Entropic Approach [34.77250498401055]
  We put forth a new theoretical framework for merging quantum information science and causal inference by exploiting entropic principles. We apply our proposed framework to an experimentally relevant scenario of identifying message senders on quantum noisy links. This approach can lay the foundations of identifying originators of malicious activity on future multi-node quantum networks.
  arXiv  Detail & Related papers  (2021-04-24T22:45:50Z)
• Experimental quantum phase discrimination enhanced by controllable indistinguishability-based coherence [13.745478068219699]
  Coherence emerges in a fundamentally different way for nonidentical and identical particles. We experimentally demonstrate this additional contribution to quantum coherence. Our experiment proves that independent indistinguishable particles can supply a controllable resource of coherence.
  arXiv  Detail & Related papers  (2021-03-27T03:50:03Z)
• Entropic uncertainty lower bound for a two-qubit system coupled to a spin chain with Dzyaloshinskii-Moriya interaction [0.0]
  In quantum information theory, the uncertainty principle is formulated using the concept of entropy. We study the dynamics of entropic uncertainty bound for a two-qubit quantum system coupled to a spin chain with Dzyaloshinskii-Moriya interaction.
  arXiv  Detail & Related papers  (2020-06-24T15:10:32Z)
• Quantum correlations and quantum-memory-assisted entropic uncertainty relation in a quantum dot system [0.0]
  Uncertainty principle is one of the comprehensive and fundamental concept in quantum theory. We will study the quantum correlation and quantum memory assisted entropic uncertainty in a quantum dot system.
  arXiv  Detail & Related papers  (2020-06-08T05:16:09Z)
• Multiple uncertainty relation for accelerated quantum information [8.598192865991367]
  We demonstrate a relativistic protocol of an uncertainty game in the presence of localized fermionic quantum fields inside cavities. A novel lower bound for entropic uncertainty relations with multiple quantum memories is given in terms of the Holevo quantity.
  arXiv  Detail & Related papers  (2020-04-21T03:29:39Z)
• Quantum Mechanical description of Bell's experiment assumes Locality [91.3755431537592]
  Bell's experiment description assumes the (Quantum Mechanics-language equivalent of the classical) condition of Locality. This result is complementary to a recently published one demonstrating that non-Locality is necessary to describe said experiment. It is concluded that, within the framework of Quantum Mechanics, there is absolutely no reason to believe in the existence of non-Local effects.
  arXiv  Detail & Related papers  (2020-02-27T15:04:08Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.