Description
Fundamentals and Properties of Multifunctional Nanomaterials outlines the properties of highly intricate nanosystems, including liquid crystalline nanomaterials, magnetic nanosystems, ferroelectrics, nanomultiferroics, plasmonic nanosystems, carbon-based nanomaterials, 1D and 2D nanomaterials, and bio-nanomaterials. This book reveals the electromagnetic interference shielding properties of nanocomposites. The fundamental attributes of the nanosystems leading to the multifunctional applications in diverse areas are further explored throughout this book.This book is a valuable reference source for researchers in materials science and engineering, as well as in related disciplines, such as chemistry and physics.- Explains the concepts and fundamental applications of a variety of multifunctional nanomaterials;- Introduces fundamental principles in the fields of magnetism and multiferroics;- Addresses ferromagnetics, multiferroics, and carbon nanomaterials.
Table of Contents
1. A glimpse into the fundamentals and properties of multifunctional nanomaterialsPart 1. Nanoscopic solids and transport properties2. Transport properties of nanoscopic solids as probed by spectroscopic techniquesPart 2. Properties of liquid crystalline nanomaterials3. Properties of multifunctional bionanomaterials of lipid A-phosphate in liquid phases and quasi-crystalline structures4. Behavior of nanoparticles within liquid crystal phasesPart 3. Properties of carbon-based nanomaterials5. Characteristics of carbon nanotubes and their nanocomposites6. Morphology-correlated mechanical properties of ionic liquid-modified multiwalled carbon nanotubes/poly(vinyl chloride) nanocomposites7. Fundamentals and properties of multifunctional graphene and graphene-based nanomaterials8. Fundamental photophysical properties of fluorescent carbon dots and their applications in metal ion sensing and bioimagingPart 4. Characteristics of magnetic nanomaterials9. Magnetic properties of doped germanium nanostructures10. Magnetic and electrochemical characteristics of carbon-modified magnetic nanoparticlesPart 5. Properties of ferroelectric nanomaterials11. Effect of particle size on structural phase transitions of lithium-modified sodium niobates (LiXNa1-XNbO3 x = 0,0.06 and 0.12)12. BiFeO3-based multiferroic materials and their propertiesPart 6. Properties of plasmonic nanomaterials13. Multifunctional plasmonic nanomaterials14. Multifunctional gold nanoparticles for biosensing: effects of surface plasmon resonance, localized surface plasmon resonance, fluorescence, and aggregationPart 7. Engineered nanomaterials for industrial applications15. The key role of metal nanoparticle in metal organic frameworks of UiO family (MOFs) for the application of CO2 capture and heterogeneous catalysis16. Embracing nanotechnology concepts in the electronics industry17. Conducting polyaniline-based nanocomposites as electromagnetic interference shielding materialsPart 8. Fundamentals of 2D nanomaterials18. Two-dimensional layered nanosheets: structure and unique properties19. MoS2, a new perspective beyond graphene20. Effect of defects and functionalization on mechanical and fracture properties of two-dimensional nanomaterialsPart 9. The impact of nanomaterials on health and safety21. Occupational health and safety measures of multifunctional nanoparticles in biomedical research and beyond
