%0 Journal Article
%T Phase Transitions Governed by the Fifth Power of the Golden Mean and Beyond
%A Hans Hermann Otto
%J World Journal of Condensed Matter Physics
%P 135-158
%@ 2160-6927
%D 2020
%I Scientific Research Publishing
%R 10.4236/wjcmp.2020.103009
%X In this contribution results from different disciplines of science were compared
to show their intimate interweaving with each other having in common the golden
ratio <i><span style=\"font-family:Verdana;\">¦Õ</span></i><span style=\"font-family:Verdana;\"> respectively its fifth power </span><i><span style=\"font-family:Verdana;\">¦Õ</span></i><sup><span style=\"font-family:Verdana;\">5</span></sup><span style=\"font-family:Verdana;\">. The research fields cover
model calculations of statistical physics associated with phase transitions, the
quantum probability of two particles, new physics of everything suggested by the
information relativity theory (</span><i><span style=\"font-family:Verdana;\">IRT</span></i><span style=\"font-family:Verdana;\">) including
explanations of cosmological relevance, the </span><i><span style=\"font-family:Verdana;\">¦Å</span></i><span style=\"font-family:Verdana;\"><span style=\"font-family:Verdana;\"><span style=\"font-family:Verdana;\">-</span></span></span><span><span><span style=\"font-family:;\" \"=\"\"><span style=\"font-family:Verdana;\">infinity
theory, superconductivity, and the </span><i><span style=\"font-family:Verdana;\">Tammes</span></i><span style=\"font-family:Verdana;\"> problem of the largest diameter of </span><i><span style=\"font-family:Verdana;\">N</span></i><span style=\"font-family:Verdana;\"> non-overlapping
circles on the surface of a sphere with its connection to viral morphology and crystallography.
Finally, </span><i><span style=\"font-family:Verdana;\">Fibo</span><span style=\"font-family:Verdana;\">nacci</span></i><span style=\"font-family:Verdana;\"> anyons proposed for topological
quantum</span><span style=\"font-family:Verdana;\"> computation (</span><i><span style=\"font-family:Verdana;\">TQC</span></i><span style=\"font-family:Verdana;\">) were
briefly described in comparison to the recently formulated reverse </span><i><span style=\"font-family:Verdana;\">Fibonacci</span></i><span style=\"font-family:Verdana;\"> approach using the </span><span style=\"font-family:Verdana;\"><em>Jani</em></span></span></span></span><span style=\"font-family:Verdana;\"><span style=\"font-family:Verdana;\"><span style=\"font-family:Verdana;\"><span style=\"white-space:nowrap;\"><em>&amp;#269;</em></span><em>ko</em></span></span></span><span style=\"font-family:Verdana;\"><span style=\"font-family:Verdana;\"><span style=\"font-family:Verdana;\"> number sequence. An architecture applicable for a quantum computer is proposed
consisting of 13-step twisted microtubules similar to tubulin microtubules of
%K Golden Mean
%K Phase Transitions
%K Hard-Hexagon Respectively Hard-Square Gas Model
%K Quantum Probability
%K Information Relativity Theory (&lt
%K i&gt
%K IRT&lt
%K /i&gt
%K )
%K &lt
%K i&gt
%K ¦Å&lt
%K /i&gt
%K -Infinity Theory
%K Superconductivity
%K &lt
%K i&gt
%K Tammes&lt
%K /i&gt
%K Problem
%K Viral Morphology
%K Helical Microtubules
%K &lt
%K i&gt
%K Jani&amp
%K #269
%K ko&lt
%K /i&gt
%K Number Sequence
%K Topological Quantum Computation
%K &lt
%K i&gt
%K Fibonacci&lt
%K /i&gt
%K Lattice
%K Crystallography
%U http://www.scirp.org/journal/PaperInformation.aspx?PaperID=101992