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Autori principali: Ting, Jonathan Yik Chang, Wood, Andrew Thomas Agars, Barnard, Amanda Susan
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2401.11737
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author Ting, Jonathan Yik Chang
Wood, Andrew Thomas Agars
Barnard, Amanda Susan
author_facet Ting, Jonathan Yik Chang
Wood, Andrew Thomas Agars
Barnard, Amanda Susan
contents The fractal dimension of a surface allows its degree of roughness to be characterized quantitatively. However, limited effort is attempted to calculate the fractal dimension of surfaces computed from precisely known atomic coordinates from computational biomolecular and nanomaterial studies. This work proposes methods to estimate the fractal dimension of the surface of any 3D object composed of spheres, by representing the surface as either a voxelized point cloud or a mathematically exact surface, and computing its box-counting dimension. Sphractal is published as a Python package that provides these functionalities, and its utility is demonstrated on a set of simulated palladium nanoparticle data.
format Preprint
id arxiv_https___arxiv_org_abs_2401_11737
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Sphractal: Estimating the Fractal Dimension of Surfaces Computed from Precise Atomic Coordinates via Box-Counting Algorithm
Ting, Jonathan Yik Chang
Wood, Andrew Thomas Agars
Barnard, Amanda Susan
Mathematical Software
Atomic Physics
Computational Physics
J.2
The fractal dimension of a surface allows its degree of roughness to be characterized quantitatively. However, limited effort is attempted to calculate the fractal dimension of surfaces computed from precisely known atomic coordinates from computational biomolecular and nanomaterial studies. This work proposes methods to estimate the fractal dimension of the surface of any 3D object composed of spheres, by representing the surface as either a voxelized point cloud or a mathematically exact surface, and computing its box-counting dimension. Sphractal is published as a Python package that provides these functionalities, and its utility is demonstrated on a set of simulated palladium nanoparticle data.
title Sphractal: Estimating the Fractal Dimension of Surfaces Computed from Precise Atomic Coordinates via Box-Counting Algorithm
topic Mathematical Software
Atomic Physics
Computational Physics
J.2
url https://arxiv.org/abs/2401.11737