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[5] viXra:2206.0151 [pdf] submitted on 2022-06-27 22:57:36
Authors: Dong-Yih Bau
Comments: 11 Pages.
Einsteinian science and Newtonian science are two sciences that seek a theory of the universe. Here, we use Einsteinian science to refer to Einstein’s later achievements in principle theory and the cosmos rather than focusing on special and general relativity. Newtonian science refers to concepts found within Weinberg’s Dreams of a Final Theory and Feynman’s The Character of Physical Law. Recently, we requested an editor of a respectable Science Citation Indexed journal to disseminate our extension of Einsteinian science for continued research and we are currently waiting. However, there may be some scientists who question our two discoveries—the success/failure system and cosmic inertia—and completely deny our extension of Einsteinian science. Nevertheless, in this paper we justify Einsteinian science and refute Newtonian science. Thus, we introduce the challenges of Polanyi’s premise of science that we then use to contrast the two sciences. Whereas Einsteinian science is based on the inertial universe, Newtonian science is based on the mechanical universe. This simple change in premise leads to a significant difference between the two sciences regarding collective research tasks, the methods of science, the laws of nature to be discovered and those already found, and their future findings. The scientific community must immediately embrace our extension of Einsteinian science and develop from it. Cosmic inertia prevails eternally.
Category: Quantum Gravity and String Theory
[4] viXra:2206.0141 [pdf] submitted on 2022-06-26 16:45:47
Authors: Boris Stoyanov
Comments: 91 Pages.
The philosophy of presented multiversum doctrina dominum article is related to the coloring of the
theoretical framework with respect to holographic complexity on extremal branes in exclusive higher-
dimensional representations. We examine holographic complexity in the doubly holographic model introduced in the current literature to study quantum extremal islands. We focus on the holographic complexity volume proposal for boundary subregions in the island phase. Exploiting the Fefferman-Graham expansion of the metric and other geometric quantities near the extremal brane, we derive the leading contributions to the complexity and interpret these in terms of the generalized volume of
the island derived from the induced higher-curvature gravity action on the extremal brane. We discuss the interpretation of path integral optimization as a uniformization problem in even dimensions. This perspective allows for a systematical construction of the higher-dimensional path integral complexity in
holographic conformal field theories in terms of Q-curvature actions. Motivated by the exceptional results, we propose a generalization of the higher-dimensional derivative actions of exotic extremal branes.
Category: Quantum Gravity and String Theory
[3] viXra:2206.0112 [pdf] replaced on 2022-07-28 10:09:53
Authors: J.A.J. van Leunen
Comments: 30 Pages. This is part of the Hilbert Book Model Project
Generating number systems reveals most of the structure and behavior of our universe. A system of separable Hilbert spaces that all share the same underlying vector space describes all aspects of the dynamic field that our universe represents. One of these Hilbert spaces acts as the background and reference platform. Via its non-separable companion, this separable Hilbert space resents the dynamic field that physicists consider the dynamic universe. All other members of the system represent moving particles.
Category: Quantum Gravity and String Theory
[2] viXra:2206.0085 [pdf] submitted on 2022-06-17 08:35:44
Authors: Paul B Merrithew
Comments: 15 Pages. CC BY-NC-ND
A model is proposed which takes energy as order in the form of a radial probability distribution. The energy associated with the distribution is calculated using the Laplacian as an operator and Planck’s constant/second as a factor. To complete the model, it is assumed that the sample rate for the elements of the distribution is determined by the distance light travels in a second. Dividing the energy associated with a 3-dimensional distribution, thus obtained, by the sample rate yields an expression for the energy associated with a 2-dimensional distribution. This expression equates to the formula for the energy of light. Dividing the 3-dimensional energy by the square of the sample rate yields as 1-dimensional energy, Planck’s constant/second. The 1-dimensional energy appears to represent the ambient energy of the universe in the form of a rotation. Using this model, various laws of classical physics are derived. Newtonian time is found to be a function of the radius of the distribution and the distance light travels in a second, and is a measure of indirection. The uncertainty principle is derived and relativity rationalized. Forces appear to arise from the reduction in order implicit in the overlap of distributions. A single order calculation of the constant of gravitation, G, is about 1 percent high. A single order calculation of the electrical potential is within 1 percent of the expected value. Consideration of higher and lower order effects yields agreement with observation within the accuracy of the numerical calculation. The possible origin of the electron, proton and neutron is discussed.
Category: Quantum Gravity and String Theory
[1] viXra:2206.0004 [pdf] submitted on 2022-06-01 11:58:17
Authors: Huaiyang Cui
Comments: 15 Pages.
It was found that ultimate acceleration can enhance the quantum gravity effects for test. If there is an ultimate acceleration β, nobody’s acceleration can exceed this limit β, in the solar system, β=2.961520e+10(m/s2). Because this ultimate acceleration is a large number, any effect connecting to β will become easy to test, including quantum gravity test. As an application, the quantum gravity theory with the ultimate acceleration provides a useful formula to calculate the space debris distribution around the earth, in this paper the calculation results agree well with the experimental observation which are a set of measurements by incoherent scattering radar of EISCAT in the Arctic circle. Using the same approach, the radius of the Sun is calculated out to be r=7e+8 (m) with a relative error 0.72%; the radius of the Earth is calculated out to be r=6.4328e+6 (m) with a relative error 0.97%.
Category: Quantum Gravity and String Theory
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