Gravity-like Attractions and Fluctuations between Entangled Systems?

viXra Pub Date : 2020-10-01 DOI:10.31219/osf.io/a6dt8

Stephane H Maes

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引用次数: 24

Abstract

In a multi-fold universe, gravity emerges from Entanglement through the multi-fold mechanisms. As a result, gravity-like effects appear in between entangled particles that they be real or virtual. Long range, massless gravity results from entanglement of massless virtual particles. Entanglement of massive virtual particles leads to massive gravity contributions at very smalls scales. Multi-folds mechanisms also result into a spacetime that is discrete, with a random walk fractal structure and non-commutative geometry that is Lorentz invariant and where spacetime nodes and particles can be modeled with microscopic black holes. All these recover General relativity at large scales and semi-classical model remain valid till smaller scale than usually expected. Gravity can therefore be added to the Standard Model. This can contribute to resolving several open issues with the Standard Model. All these phenomena result from the observation that attractive gravity-like potentials appear in spacetime between entangled systems, because of the mechanisms proposed in a multi-fold universe to address the EPR paradox. An immediate implication, and opportunity to validate or falsify the model, is that gravity-like effects and fluctuation are predicted to appear between, around or near entangled systems; we just need check if this is encountered in the real world. This paper discuss situations where attraction due to entanglement, and hence gravity like effects or fluctuations, could be encountered. For example, within or near quantum matter like superconductors or (Bose Einstein Condensates) BECs or within Qubits. One could argue that some indications exist that some of these effects could already have already been observed. We are really seeking falsifiability or validation opportunities for the multi-fold mechanisms. Early considerations are encouraging. Discussing some related experiments led us to also address how shielding is correctly modeled with multi-fold mechanisms: Faraday cages do not weaken gravity!

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类引力吸引和纠缠系统之间的涨落?

在多重宇宙中，引力通过多重机制从纠缠中产生。结果，在纠缠的粒子之间出现了类似引力的效应，它们是真实的还是虚拟的。远距离无质量引力是由无质量虚粒子的纠缠产生的。大质量虚粒子的纠缠导致在非常小的尺度上产生巨大的引力贡献。多重折叠机制也导致了一个离散的时空，具有随机行走的分形结构和洛伦兹不变量的非交换几何，其中时空节点和粒子可以用微观黑洞来建模。所有这些都在大尺度上恢复了广义相对论，半经典模型在比通常预期更小的尺度上仍然有效。因此，引力可以加入到标准模型中。这有助于解决标准模型的几个开放问题。所有这些现象都是由于在多重宇宙中提出的解决EPR悖论的机制，在纠缠系统之间的时空中出现了吸引的类引力势。一个直接的含义，以及验证或证伪模型的机会，是预测在纠缠系统之间，周围或附近出现类引力效应和波动;我们只需要检查在现实世界中是否会遇到这种情况。本文讨论了由于纠缠引起的吸引以及由此产生的类重力效应或涨落可能遇到的情况。例如，在量子物质内部或附近，如超导体或(玻色爱因斯坦凝聚)bec或量子位。有人可能会争辩说，存在一些迹象表明，其中一些影响可能已经被观察到。我们确实在寻求多重机制的可证伪性或验证机会。早期的考虑令人鼓舞。通过讨论一些相关的实验，我们还讨论了如何用多重机制正确地模拟屏蔽:法拉第笼不会削弱重力!

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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