Resistance distance and sharp bounds of two-mode electrical networks

Ullah, Asad; Salman, Salima; Zaman, Shahid

doi:10.1088/1402-4896/ad5c16

Phys. Scr.

2024

DOI: 10.1088/1402-4896/ad5c16

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Resistance distance and sharp bounds of two-mode electrical networks

Asad Ullah,

Salima Salman,

Shahid Zaman

Abstract: Electrical networks are ubiquitous in our daily lives, ranging from small integrated circuits to large-scale power systems. These networks can be easily represented as graphs, where edges represent connections and vertices represent electric nodes. The concept of resistance distance originates from electrical networks, with this term used because of its physical interpretation, where every edge in a graph G is assumed to have a unit resistor. The applications of resistance distance extend to various fields suc… Show more

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Cited by 3 publications

References 59 publications

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Coronene, a benzenoid compound, holds significant potential for applications in diverse fields, including organic chemistry, materials science, and pharmaceuticals. This study focuses on the structural analysis of Zigzag Hexagonal Coronene Fractal (ZHCF), a unique molecular configuration with significant implications for materials science and nanotechnology. Utilizing topological indices across two-dimensional chemical structure networks, we evaluate critical physicochemical properties of these molecules. Analytical expressions for a wide range of connection number-based topological descriptors are derived, enabling the prediction of properties such as entropy, enthalpy of vaporization, boiling point, and the acentric factor. The use of these mathematical tools provides a deeper understanding of the molecular connectivity and distribution patterns within the ZHCF framework, revealing insights into its stability and potential functionality. The results demonstrate how these indices can effectively capture the structural nuances of complex molecular graphs, aiding in the rational design of advanced nanomaterials with improved optical and electronic properties. This research not only showcases the predictive power of topological descriptors but also highlights the potential applications of coronoid-based structures in creating high-performance materials for various technological and scientific advancements. The findings pave the way for future exploration of coronoid structures in developing innovative solutions across diverse fields.

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et al. 2024

Int. J. Mod. Phys. B

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Modeling and computation of molecular descriptors play a crucial role in understanding the properties and characteristics of novel materials like [Formula: see text]-graphyne, the next-generation wonder material. Triangular [Formula: see text]-graphyne is an intriguing two-dimensional carbon-based material with diverse potential applications due to its unique electronic, mechanical, and thermal properties. Triangular [Formula: see text]-graphyne, a distinctive form of carbon allotrope, has garnered substantial interest as a result of its extraordinary characteristics. The notable value lies in its ability to be utilized in diverse domains for potential applications. The interconnected mesh structure of Triangular [Formula: see text]-graphyne exhibits exceptional mechanical strength and exceptional electron-transporting properties. This makes it a promising material for the development of high-performance electronic devices, such as transistors and sensors. Furthermore, gamma graphyne possesses excellent thermal stability, which makes it suitable for applications in the field of energy storage and conversion. It has the potential to be used as a catalyst in fuel cells or as an electrode material in supercapacitors. In this study, we utilize graph theory to dissect the molecular structure of triangular [Formula: see text]-graphyne, leading to the derivation of specific mathematical formulas for essential degree-based molecular characteristics. These findings can be instrumental in examining the correlations between the structure and properties of [Formula: see text]-graphyne. This paper focuses on two structures made from hexagonal honeycomb graphite lattices, like triangular [Formula: see text]-graphyne and triangular [Formula: see text]-graphyne chains with respect to some degree-based topological indices. The results obtained will aid in the investigation of the structure-property relationships in [Formula: see text]-graphyne.

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Resistance distance and sharp bounds of two-mode electrical networks

Cited by 3 publications

References 59 publications

Computational insights into flavonoid molecular structures and their QSPR modeling via degree based molecular descriptors

Computational insights into flavonoid molecular structures and their QSPR modeling via degree based molecular descriptors

Fractal configurations of zigzag hexagonal type coronoid molecules: Graph-theoretical modeling and its impact on physicochemical behavior

Computational modeling of triangular γ-graphyne using advanced topological methods

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