Tehran University of Medical Sciences

Science Communicator Platform

Share By
Multiphase Approach for Calculation of Tunneling Conductivity of Graphene-Polymer Nanocomposites to Optimize Breast Cancer Biosensors Publisher



Zare Y1 ; Rhee KY2
Authors

Source: Composites Science and Technology Published:2023


Abstract

A multiphase approach for the estimation of the electrical conductivity of graphene-based products from the properties of graphene, tunnels, and interphase is proposed. First, a simple model estimates the conductivity of interphase around the nanosheets, and subsequently, the conductivity of pseudoparticles containing graphene, tunnels, and interphase is estimated. Finally, a progressed model estimates the conductivity of the systems containing a polymer and pseudoparticles. The predictions of the multiphase technique were evaluated through comparison with experimented values and by parametric analyses. The predictions showed good agreement with the experimental values. Furthermore, the results of parametric studies supported the correctness of the multiphase technique. Thin and large graphene nanosheets can increase the conductivity to 0.14 S/m, and a high filler concentration and the presence of large tunnels could enhance the conductivity to 50 S/m. The maximum conductivity of 0.016 S/m is gained by an interphase depth of 10 nm and a filler conduction of 2.5 × 105 S/m. The developed model can be used for optimizing breast cancer biosensors since the conductivity is the main factor for detection. © 2022 Elsevier Ltd
Related Docs
View other Related Docs
1. Electrical Conductivity of Graphene-Containing Composites by the Conduction and Volume Share of Networked Interphase and the Properties of Tunnels Applicable in Breast Cancer Sensors, Journal of Materials Science (2022)
2. Progressing of Kovacs Model for Conductivity of Graphene-Filled Products by Total Contact Resistance and Actual Filler Amount, Engineering Science and Technology# an International Journal (2022)
3. Effect of Contact Number Among Graphene Nanosheets on the Conductivities of Tunnels and Polymer Composites, Scientific Reports (2023)
Other Related Docs
4. Predicting of Tunneling Resistivity Between Adjacent Nanosheets in Graphene–Polymer Systems, Scientific Reports (2023)
5. Simulating of Effective Conductivity for Grapheme–Polymer Nanocomposites, Scientific Reports (2023)
6. From Nano to Macro in Graphene-Polymer Nanocomposites: A New Methodology for Conductivity Prediction, Colloids and Surfaces A: Physicochemical and Engineering Aspects (2024)
7. An Innovative Model for Conductivity of Graphene-Based System by Networked Nano-Sheets, Interphase and Tunneling Zone, Scientific Reports (2022)
8. Development of Kovacs Model for Electrical Conductivity of Carbon Nanofiber–Polymer Systems, Scientific Reports (2023)
9. Modeling of Electrical Conductivity for Graphene-Based Systems by Filler Morphology and Tunneling Length, Diamond and Related Materials (2023)
10. Effect of Contact Resistance on the Electrical Conductivity of Polymer Graphene Nanocomposites to Optimize the Biosensors Detecting Breast Cancer Cells, Scientific Reports (2022)
11. Modeling of Electrical Conductivity for Polymer–Carbon Nanofiber Systems, Materials (2022)
12. Assessment of Electrical Conductivity of Polymer Nanocomposites Containing a Deficient Interphase Around Graphene Nanosheet, Scientific Reports (2024)
13. Advancement of the Power-Law Model and Its Percolation Exponent for the Electrical Conductivity of a Graphene-Containing System As a Component in the Biosensing of Breast Cancer, Polymers (2022)
14. Percolation Onset and Conductivity of Nanocomposites Assuming an Incomplete Dispersion of Graphene Nanosheets in a Polymer Matrix, Physical Chemistry Chemical Physics (2023)
15. Modeling of Electrical Conductivity for Graphene-Filled Products Assuming Interphase, Tunneling Effect, and Filler Agglomeration Optimizing Breast Cancer Biosensors, Materials (2022)
16. Effects of a Deficient Interface, Tunneling Size and Interphase Depth on the Percolation Inception, Percentage of Graphene in the Nets and Conductivity of Nanocomposites, Diamond and Related Materials (2024)
17. Progressing of a Power Model for Electrical Conductivity of Graphene-Based Composites, Scientific Reports (2023)
18. Development of Jang–Yin Model for Effectual Conductivity of Nanocomposite Systems by Simple Equations for the Resistances of Carbon Nanotubes, Interphase and Tunneling Section, European Physical Journal Plus (2021)
19. Development of an Advanced Takayanagi Equation for the Electrical Conductivity of Carbon Nanotube-Reinforced Polymer Nanocomposites, Journal of Physics and Chemistry of Solids (2021)
20. Supposition of Graphene Stacks to Estimate the Contact Resistance and Conductivity of Nanocomposites, Applied Mathematics and Mechanics (English Edition) (2024)