Advanced Functional Polymers and Their Synergistic Role in Smart Composite Materials for Sustainable Industrial Applications

Year : 2025 | Volume : 13 | Special Issue 04 | Page : 12-27
    By

    Bindiya Jain,

  • Vaishali Praveen,

  • Yashika Saini,

  • Satya Prakash Awasthi,

  • Sumit Kumar Kapoor,

  1. Associate Professor, Faculty of Computer Science and Engineering, Poornima University, Jaipur, Rajasthan, India
  2. Associate Professor, Faculty of Engineering and Technologies, Poornima University, Jaipur, Rajasthan, India
  3. Assistant Professor, Faculty of Computer Science and Engineering, Poornima University, Jaipur, Rajasthan,
  4. Associate Professor, Department of Computer Science and Engineering, Amity University, Gwalior, Madhya Pradesh, India
  5. Associate Professor, Faculty of Computer Science and Engineering, Poornima University, Jaipur, Rajasthan, India

Abstract

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Advanced functional polymers have revolutionized composite materials, offering enhanced properties such as self-healing, electrical conductivity, environmental adaptability, and high mechanical strength. These innovations are reshaping industries by enabling smarter, more efficient, and sustainable solutions. Functional polymers play a pivotal role in producing high-performance composite materials to meet the growing demands of sustainable industrial applications. Significant improvements in material properties mechanical strength, durability, thermal stability, and recyclability are achieved through the integration of advanced polymers with nanoparticles, fibres, and bio-based composites. These advancements reduce environmental impacts across sectors like automobiles, aerospace, construction, and renewable energy. This study highlights key quantitative outcomes and findings from case studies, demonstrating the significance of advanced functional polymers. For instance, energy storage systems show a 40% efficiency increase, biomedical applications achieve 25% enhanced drug delivery accuracy, solar panels experience a 15% energy output boost, and industrial water purification systems report a 30% reduction in operational costs. These results underscore the vital role of functional polymers in driving material innovations while promoting environmental and economic sustainability. The paper emphasizes eco-friendly production processes, the role of advanced functional polymers in minimizing waste, reducing energy consumption, and utilizing renewable resources. Their contributions to reducing carbon footprints, extending product lifespans, and enabling self-healing, electrical conductivity, and environmental responsiveness are explored. The recyclability and biodegradability of these polymers further support the transition to a circular economy. This research discusses innovative methodologies to develop and optimize smart composites, focusing on material selection, fabrication techniques, and sustainability assessments. Advanced experimental techniques with modelling approaches, it provides insights into a new generation of composite materials that meet contemporary industry demands. The findings pave the way for large-scale industrial adoption of advanced functional polymers, fostering a more circular and sustainable future.

Keywords: Advanced functional polymers, smart composite materials, sustainable industrial applications, thermal stability, mechanical strength, high-performance composites.

[This article belongs to Special Issue under section in Journal of Polymer and Composites (jopc)]

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How to cite this article:
Bindiya Jain, Vaishali Praveen, Yashika Saini, Satya Prakash Awasthi, Sumit Kumar Kapoor. Advanced Functional Polymers and Their Synergistic Role in Smart Composite Materials for Sustainable Industrial Applications. Journal of Polymer and Composites. 2025; 13(04):12-27.
How to cite this URL:
Bindiya Jain, Vaishali Praveen, Yashika Saini, Satya Prakash Awasthi, Sumit Kumar Kapoor. Advanced Functional Polymers and Their Synergistic Role in Smart Composite Materials for Sustainable Industrial Applications. Journal of Polymer and Composites. 2025; 13(04):12-27. Available from: https://journals.stmjournals.com/jopc/article=2025/view=0


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Special Issue Subscription Review Article
Volume 13
Special Issue 04
Received 23/01/2025
Accepted 18/02/2025
Published 10/05/2025
Publication Time 107 Days
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