The collection of topics in this book reflects the diversity of recent advances in nanoelements formation and interactions in nanosystems with a broad perspective that is useful for scientists as well as for graduate students and engineers.
One of the main tasks in making nanocomposites is building the dependence of the structure and shape of the nanoelements, forming the basis for the composite of their sizes. This is because with an increase or a decrease in the specific size of nanoelements, their physical–mechanical properties such as the coefficient of elasticity, strength, and deformation parameter, vary by over one order. The calculations show that this is primarily due to a significant rearrangement of the atomic structure and the shape of the nanoelement. The investigation of the above parameters of the nanoelements is technically complicated and laborious because of their small sizes. When the characteristics of powder nanocomposites are calculated, it is also very important to take into account the interaction of the nanoelements since the changes in their original shapes and sizes in the interaction process and during the formation of the nanocomposite can lead to a significant change in its properties and a cardinal structural rearrangement. In addition, the studies show the appearance of the processes of the ordering and self-assembling leading to a more organized form of a nanosystem. The above phenomena play an important role in nanotechnological processes. They allow nanotechnologies to be developed for the formation of nanostructures by the self-assembling method (which is based on self-organizing processes) and building up complex spatial nanostructures consisting of different nanoelements.
The study of the above dependences based on the mathematical modeling methods requires the solution of the aforementioned problem at the atomic level. This requires large computational aids and computational time, which makes the development of economical calculation methods urgent. The objective of this volume is the development of such a technique in various nanosystems.
Nanoscale Science and Technology: An Overview
Nanoelement Manufacturing: Self-Assembly
Nanomaterials: Properties and Application
Modeling and Simulation
Molecular Simulation for Nanomaterials
Numerical Simulation of Nanoelements
Numerical Study of Axial and Coaxial Electrospinning Process
Dr. Sabu Thomas is the director of the School of Chemical Sciences, Mahatma Gandhi University, Kottayam, India. He is also a full professor of polymer science and engineering and the director of the International and InterUniversity Centre for Nanoscience and Nanotechnology of the same university. He is a fellow of many professional bodies. Professor Thomas has authored or co-authored many papers in international peer-reviewed journals in the area of polymer processing. He has organized several international conferences and has more than 420 publications, 11 books, and 2 patents to his credit. He has been involved in a number of books both as author and editor. He is a reviewer to many international journals and has received many awards for his excellent work in polymer processing. His h Index is 42. Professor Thomas was ranked five on the list of Most Productive Researchers in India in 2008.
Saeedeh Rafiei is a professional textile engineer and a Research Fellow at Technopark, Kerala. Saeed Rafiei earned a BSc in textile engineering, an MSc on textile engineering, and has published several papers in journals and conferences.
Shima Maghsoodlou is a professional textile engineer and a Research Fellow at Technopark, Kerala.Shima Maghsoodlou received a BSc in textile engineering, an MSc in textile engineering, and has published several papers in journals and conferences.
Arezoo Afzali is a professional textile engineer and a Research Fellow at Technopark, Kerala. She has a BSc in textile engineering, an MSc in textile engineering, and has published several papers in journals and conferences.