Development of Conductive Polymer-Based Materials for Flexible Integrated Electronic Applications

Authors

  • Adrian Maulana University of Al Azhar Medan
  • M Habil Rifanza University of Al Azhar Medan
  • Jefri Saidi Rambe University of Al Azhar Medan

DOI:

https://doi.org/10.31004/jutin.v9i1.54919

Keywords:

Conductive Polymers, Flexible Electronics, Composite Materials, Electronic Device Integration, Environmentally Friendly, Fabrication

Abstract

As electronic devices become more common, EMI is turning into a bigger issue. Conductive polymer composites are considered promising because they are lightweight, resistant to corrosion, easy to shape, and stable. Adding conductive fillers such as graphene, MXene, carbon fibers, or certain metals can further improve their ability to block EMI and conduct heat and electricity. These materials are very thin, but they can block sounds louder than 80 dB. 3D printing and template fabrication are two new ways of making things that allow you to create strong and flexible conductive networks with little filler. However, there are still some issues that need to be addressed, such as how to distribute the filler evenly, control the microstructure, and keep the polymer-filler interface dense. Some proposed improvements are to modify the interface, mix different types of fillers, and build structures that are porous or have more than one layer. If designed and manufactured correctly, these conductive polymer composites can be used in flexible electronics, wearable devices, and next-generation thermal management systems

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Published

2026-01-20

How to Cite

Maulana, A., Rifanza, M. H., & Rambe, J. S. (2026). Development of Conductive Polymer-Based Materials for Flexible Integrated Electronic Applications . Jurnal Teknik Industri Terintegrasi (JUTIN), 9(1), 958–964. https://doi.org/10.31004/jutin.v9i1.54919

Issue

Vol. 9 No. 1 (2026): January

Section

Articles of Research

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Copyright (c) 2026 Adrian Maulana, M Habil Rifanza, Jefri Saidi Rambe

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This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

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