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Autori principali: Schreivogl, Paul, Schweiger, Richard
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2412.16011
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author Schreivogl, Paul
Schweiger, Richard
author_facet Schreivogl, Paul
Schweiger, Richard
contents The techniques developed for matrix models and fuzzy geometry are powerful tools for representing strings and membranes in quantum physics. We study the representation of fuzzy surfaces using these techniques. This involves constructing graphs and writing their coordinates and connectivity into matrices. To construct arbitrary graphs and quickly change them, we use 3D software. A script generates the three matrices from the graphs. These matrices are then processed in Wolfram Mathematica to calculate the zero modes of the Dirac operator. Our first result shows the quantization of a two-dimensional Trefoil knot. Additional examples illustrate various properties and behaviors of this process. This helps us to gain a deeper understanding of fuzzy spaces and zero-mode surfaces. This work contributes to advancing the understanding of visualization aspects in fuzzy geometry.
format Preprint
id arxiv_https___arxiv_org_abs_2412_16011
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Fuzzy-Space Engineering
Schreivogl, Paul
Schweiger, Richard
High Energy Physics - Theory
The techniques developed for matrix models and fuzzy geometry are powerful tools for representing strings and membranes in quantum physics. We study the representation of fuzzy surfaces using these techniques. This involves constructing graphs and writing their coordinates and connectivity into matrices. To construct arbitrary graphs and quickly change them, we use 3D software. A script generates the three matrices from the graphs. These matrices are then processed in Wolfram Mathematica to calculate the zero modes of the Dirac operator. Our first result shows the quantization of a two-dimensional Trefoil knot. Additional examples illustrate various properties and behaviors of this process. This helps us to gain a deeper understanding of fuzzy spaces and zero-mode surfaces. This work contributes to advancing the understanding of visualization aspects in fuzzy geometry.
title Fuzzy-Space Engineering
topic High Energy Physics - Theory
url https://arxiv.org/abs/2412.16011