Particles, Especially Virtual Particles, in a Multi-fold Universe vs. QFT

viXra Pub Date : 2020-10-01 DOI:10.31219/osf.io/x8pks
Stephane H Maes
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引用次数: 11

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. In this paper, we discuss the point of view of the virtual particles used to explain gravity emergence from entanglement and in particular position their use versus the more conventional view on virtual particles in QFT. Indeed, besides the fact that QFT has challenges to model particles, there are some strong views on what is or is not appropriate when it comes to involving virtual particles in conventional QFT, or vacuum fluctuations for that matter. The proposed multi-fold mechanisms on the other hand rely first and foremost on the concept of particles, with modifications to conventional QFT. In that context virtual particle play a central role. Besides evangelizing the need to evolve QFT, we also review how virtual particles are key to the notion of small scale non negligible addition of gravity to the standard model, and to a proposal for Ultimate Unification where al particles convey gravity and their proper interactions. We also discuss how this model is key and aligned to the area laws of blacks holes, Hawking’s radiation and the absence of gravity shielding even when using virtual particle. This discussion will also offer some perspectives on QFT in curved spacetime. The bottom line is that there are no contradiction with the main views on virtual particles of conventional QFT proposed with multi-fold universe mechanisms and that in fact, while hard to formulate, the use of virtual particles could also be modeled with fields and associated multi-fold fields. We also discuss comparing our model using pairs of entangled virtual particles versus models using only (or in addition) pairs of entangled gravitons. Such a multi-fold model with only gravitons may recover the same results or differ depending on how massive gravitons would be modeled in these new models. But we end up still recommending only a model where gravitons live in AdS(5).
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多重宇宙中的粒子,尤其是虚粒子与QFT
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。在本文中,我们讨论了用于解释纠缠产生引力的虚粒子的观点,特别是它们与QFT中更传统的虚粒子观点的对比。事实上,除了量子傅立叶变换对粒子建模有挑战这一事实外,对于在传统量子傅立叶变换中涉及虚粒子或真空涨落时,什么是合适的,什么是不合适的,也存在一些强烈的观点。另一方面,提出的多重机制首先依赖于粒子的概念,并对传统的量子傅立叶变换进行了修改。在这种情况下,虚粒子起着中心作用。除了宣扬演化量子力学的必要性之外,我们还回顾了虚粒子是如何在标准模型中加入小尺度不可忽略的引力概念的关键,以及最终统一的提议,其中所有粒子都传递引力及其适当的相互作用。我们还讨论了这个模型是如何与黑洞的面积定律、霍金辐射以及即使在使用虚拟粒子时也没有引力屏蔽的情况下保持一致的。本讨论还将提供一些关于弯曲时空中量子傅立叶变换的观点。底线是,这与传统QFT中关于多重宇宙机制下虚粒子的主要观点并不矛盾,事实上,尽管难以表述,但虚粒子的使用也可以用场和相关的多重场来建模。我们还讨论了使用纠缠虚粒子对的模型与仅使用(或添加)纠缠引力子对的模型的比较。这样一个只有引力子的多重模型可能会恢复相同的结果,也可能会有所不同,这取决于在这些新模型中如何模拟大质量的引力子。但我们最终还是只推荐一个引力子存在于AdS(5)中的模型。
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