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| viXra.org > Condensed Matter > 2603 |
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[2] viXra:2603.0072 [pdf] submitted on 2026-03-14 20:39:44
Authors: Farid Abrari
Comments: This article is in English and has 7 pages.
The singularity of a black hole with a quantum index b was previously shown to be consisted of b concentric spherical shells of a constant diametral step size A, corresponding to a fundamental resolution interval in nature. An interior shell j was found to be a condensation of a Primordial Stem Particles (PSP) of mass m = h/Ac, at excitation state j and momentum jmc. The spatial uncertainty of the constituents at this excitation state was found to be jA, therefore, confining the particles to the very surface of the shell of diameter jA. The number of constituents N_1 = A^2/(4L_p^2) of the innermost shell j = 1 was found to be the quanta of particle count in the singularity, such that particle count on a shell of index j was N_j = (3j^2 − 3j + 1) N_1. Invoking Tammes’s conjecture, we have shown in this article that the microstructure of the black hole singularity is consisted of a distinct set of curved hexagonal lattices that are wrapped into the spherical shells. It is shown that the distance of the constituents on the innermost shell is d_1 = √ (8π/√3) Lp. The microstructure gets progressively finer towards the outer shells. In the outermost shell of the singularity of the supermassive black holes, the lower limit d_infty is approaching to √(8π/3) Lp. It is also noted that a centered hexagonal tessellation naturally emerges from N_j law which is a remarkable hint of consistency in the proposed theory of black holes.
Category: Condensed Matter
[1] viXra:2603.0022 [pdf] replaced on 2026-03-10 14:00:55
Authors: Hans Hermann Otto
Comments: 6 Pages.
We address attention to the 3D lattice match between hexagonal lonsdaleite, a carbon allotrop denser and harder than diamond with a higher carrier mobility, and tetragonal stishovite (rutile structure). Both compounds are obtainable via shock wave synthesis route. Stishovite seeding may lower the high-pressure and low temperature synthesis conditions for lonsdaleite as a coming material for quantum computer chips better withstanding solar wind damage. The chips could be made of a forest of lonsdaleite nanorods with defect center based addressable high-fidelity and non-destructive qubits. Material science as well as geochemistry may gain profite from the remarkable three-dimensional lattice coincidence between stishovite and lonsdaleite as a groundbreaking suggestion. Interestingly, carbon dioxide can adopt the rutile structure at extreme conditions of pressure and temperature. This paws the way for new oxygen defect based research on lonsdaleite as chip material.
Category: Condensed Matter
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