Polymer-Plastics Technology and Materials, Vol. 65, Issue 10, Features Latest Research in DLP 3D Printing Composites and Multifunctional Food Packaging

Taylor & Francis Online UK

Overview

The 2026 Volume 65, Issue 10 of ‘Polymer-Plastics Technology and Materials’ has been published, featuring extensive new research on polymer and plastic materials. Highlights include a comprehensive performance evaluation of DLP 3D printing composite resins, structural and electrical property analyses of PVDF/ZnTiO3 composites, and a review of multifunctional design strategies for food packaging films, emphasizing tear resistance and barrier properties. These studies represent significant advancements in addressing modern environmental challenges and contribute to the development of next-generation materials for a sustainable future.

In Depth

Key Findings

Volume 65, Issue 10 of ‘Polymer-Plastics Technology and Materials,’ published in 2026, presents several groundbreaking research findings in the field of polymer and plastic materials. This issue includes a comprehensive performance evaluation of composite resins for DLP (Digital Light Processing) 3D printing, a detailed analysis of the structure, morphology, and electrical properties of PVDF/ZnTiO3 composites, and a review on multifunctional design strategies for food packaging films that combine tear resistance and permeation barrier properties, addressing current environmental concerns.

Technical & Clinical Details

Research on DLP 3D printing composite resins in this issue delves into evaluating the mechanical strength, thermal stability, and hardness of various composite resins to further advance DLP technology, known for its high-resolution and precise fabrication capabilities. This research aims to accelerate the selection and development of optimal resin materials for specific industrial applications. Furthermore, studies on PVDF (polyvinylidene fluoride) and ZnTiO3 (zinc titanate) composites demonstrate that combining these materials enhances piezoelectric and dielectric properties, showing potential for applications in electronic devices like sensors and actuators. A particularly notable contribution is the review on multifunctional food packaging films, which proposes new film designs that are tear-resistant and effectively block oxygen and water vapor transmission. This addresses critical issues such as plastic waste and the need to extend food shelf life, integrating biodegradable polymers, nanocomposites, and active packaging technologies.

Background & Context

Polymer materials are fundamental to various industries, including electronics, automotive, medical, and packaging. The evolution of 3D printing technology has enabled customizable parts manufacturing and rapid prototyping, significantly transforming industries. Simultaneously, growing environmental awareness has generated new demands for the sustainability and functionality of packaging materials. High-performance polymers like PVDF are valued for their properties in sensors and energy storage devices, with composite materials promising further performance enhancements. These studies provide foundational knowledge to solve existing challenges in respective fields and accelerate next-generation product development.

Strategic Significance & Outlook

The research featured in this issue points to crucial directions shaping the future of polymer science. Optimization of DLP 3D printing composite resins will enable higher-performance additive manufacturing, revolutionizing the production of medical devices and complex industrial parts. The study on PVDF/ZnTiO3 composites will contribute to enhancing smart materials and IoT devices, while the multifunctional design of food packaging films will be indispensable for achieving a sustainable society by reducing both food waste and plastic waste. Further research and development in these areas are expected to lead to more efficient and environmentally friendly material solutions.