Multidisciplinary Approach On Computational Analysis Of Composite Materials
Main Article Content
Abstract
Composite materials find extensive application in high-end industries like aerospace technology, heavy machinery manufacturing, and spacecraft construction. Recent advancements show how multifunctional composite materials (MFCMs) are becoming more and more common. Composite materials continue to be enhanced, innovated upon, and eventually replaced with metals despite undergoing extensive destructive and non-destructive testing. This ongoing development highlights the durability and resilience of these materials. The objective of the current study is to review relevant topics for modern multifunctional composite materials. The majority of the literature is devoted to nanomaterial-based MFCMs and highlights the structural properties of these materials, including stiffness, tensile strength, damping, strength, and thermal stability. electromagnetic interference (EMI), thermal electrical properties, and biodegradability shielding are examples of non-structural features. The study emphasizes how crucial these characteristics are to the creation of MFCMs for a range of uses.