Enhanced Synthesis Methods and Comprehensive Material Response Analysis in Alloy-Infused Nanocomposites

Open Access

Year : 2024 | Volume : | : | Page : –
By

Dr. Vikram Keru Dhatrak,

Dr. Prachi Subhash Kapse,

Dr. Kunal Kishor Chandan,

Dr. Rahul Atmaram Wagh,

Dr. Gajanan Zumbarlal Jadhav,

  1. Assistant Professor Sandip Institute of Technology & Reserch Centre, Nashik Maharashtra India
  2. Assistant Professor Sandip Institute of Technology & Reserch Centre, Nashik Maharashtra India
  3. Assistant Professor Sandip University Sijoul Bihar India
  4. Assistant Professor Sandip University, Nashik Maharashtra India
  5. Assistant Professor Sandip Institute of Technology & Reserch Centre, Nashik Maharashtra India

Abstract

This study looks into the most advanced ways to make alloy-infused nanocomposites and how they react to different materials. It focuses on how these nanocomposites can be used to process and make plastics and composites. A lot of people are interested in alloy-infused nanocomposites because they have better mechanical, thermal, and electrical qualities than regular composites. The goal of this study is to improve the methods used for making nanocomposites so that the metal nanoparticles are evenly distributed and fully integrated into the polymer matrix. This will make the nanocomposites work better overall. We start by looking at different ways to make metal nanoparticles, such as in-situ polymerization, melt mixing, and solution casting, to find the best way to make them evenly spread. The study also looks into how different production factors, like temperature, mixing speed, and the amount of nanoparticles used, affect the nanocomposites’ structure and functional qualities. A full material reaction study is done to check the synthetic nanocomposites’ mechanical qualities (such as tensile strength, stiffness, and impact resistance), temperature stability, and ability to conduct electricity. To look at the nanoparticles’ architecture and how well they are spread out, advanced methods like scanning electron microscopy (SEM), transmission electron microscopy (TEM), and X-ray diffraction (XRD) are used. The findings show that using the best methods for manufacturing greatly improves the material qualities of alloy-infused nanocomposites. This means that these materials can be used in many different fields, such as the electronics, aircraft, and automobile industries. The study also looks at the problems that come up with making these synthesis methods scalable and repeatable, giving us ideas for possible answers that could be used in industry.

Keywords: Alloy-Infused Nanocomposites, Advanced Synthesis Methods, Material Response Analysis, Polymer Composites, Mechanical Properties, Thermal Stability

How to cite this article: Dr. Vikram Keru Dhatrak, Dr. Prachi Subhash Kapse, Dr. Kunal Kishor Chandan, Dr. Rahul Atmaram Wagh, Dr. Gajanan Zumbarlal Jadhav. Enhanced Synthesis Methods and Comprehensive Material Response Analysis in Alloy-Infused Nanocomposites. Journal of Polymer and Composites. 2024; ():-.
How to cite this URL: Dr. Vikram Keru Dhatrak, Dr. Prachi Subhash Kapse, Dr. Kunal Kishor Chandan, Dr. Rahul Atmaram Wagh, Dr. Gajanan Zumbarlal Jadhav. Enhanced Synthesis Methods and Comprehensive Material Response Analysis in Alloy-Infused Nanocomposites. Journal of Polymer and Composites. 2024; ():-. Available from: https://journals.stmjournals.com/jopc/article=2024/view=168250

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Ahead of Print Open Access Review Article
Volume
Received May 16, 2024
Accepted June 26, 2024
Published July 16, 2024
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