Thermo-magneto-electric quantized resistance of rolled shape conductors modified polymer nanocomposites

Abstract

A conductive network model approach is developed based on induced magneto-electric modes to investigate the thermal energy effect on the quantized resistance of a conductive polymer composite with rolled shape conductors. The concept of modes describes the characterization of energy levels in accordance with the thermal energy when the size of the solid is scaled down to a finite size. The focus relates the parameters of micro-scale phenomenon to macro-scale resistance. Along with the resistance dependence on the proportion of the conductor, the effect of the geometry and tunneling resistance on percolation threshold is simulated. The other part of the modeling approach consists of the resistance change and the ensuing conductor displacement computation. Analyses of piezoresistivity that take tunneling behavior in the percolation transition zone into account show good agreement with experimental data. By increasing the mobility of the charges, the magnetic field increases the electrical conductivity and improves electron transport states affected by the applied field. As a result of scaling the sensitivity to lower values, smaller conductors improve the effectiveness of the conductive network in facilitating charge transport. © The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2025.