Modeling Electrical Transport in Random Networks Composed of Metal-Oxide Nanowires: The Transition from Junction-Dominated to Nanowire-Dominated Regime
Year: 2025
Authors: Ponzoni., A.
Autors Affiliation: Natl Inst Opt Natl Res Council CNR INO, Via Branze 45, I-25123 Brescia, Italy; Natl Inst Opt Natl Res Council CNR INO, Unit Lecco, Via Previati 1-E, I-23900 Lecce, Italy; Univ Brescia, Dept Informat Engn, Via Branze 38, I-25123 Brescia, Italy.
Abstract: Random networks of metal oxide nanowires are of great technological interest in a variety of applications. Unveiling how the properties of the elementary components of the network, namely, nanowires and nanowire-nanowire junctions, may emerge as macroscopic functionalities is a fundamental issue. However, the disordered nature of the network and difficulties in estimating important properties, such as the junction contact radius, hinder the understanding and exploitation of these materials. This paper develops a model suitable for discussing the electrical resistance of the network and its transition from the junction-dominated regime to the nanowire-dominated regime, based on the nanowire characteristic lengths and energies. The result is achieved by integrating recent network theories with the equations of semiconducting metal oxides. Constraints imposed by the thermodynamics of contact mechanics are introduced to provide a lower limit for the unknown junction contact radius. Focusing on the literature of gas sensing, the model provides a theoretical background to frame the relationship between gas-sensing properties and the surface termination of nanowires in the context of network theories.
Journal/Review: ADVANCED THEORY AND SIMULATIONS
More Information: This research has been partially funded by the European Union – NextGeneration EU, within PRIN 2022, PNRR M4C2, Project Accurate fermentation monitoring through multi-sensorial approach 2022CZEXJA [CUP B53D23002520006]KeyWords: electrical transport; nanowires; random networks; SnO2; ZnODOI: 10.1002/adts.202500496
