Free download Nano Surface Chemistry By Morton Rosoff

Authors of: Nano Surface Chemistry By Morton Rosoff

Morton Rosoff

Table of Contents in Nano Surface Chemistry By Morton Rosoff

This volume offers a comprehensive exploration of the science and technology behind nanoscale materials, interfaces, and applications. With contributions from leading researchers across disciplines, the book presents cutting-edge findings and techniques that define the field of nanoscience today. It begins with a preface, contributors list, and an introduction, which together set the stage for the in-depth, interdisciplinary content to follow.

The book is organized into seventeen chapters, each of which explores a unique aspect of nanotechnology, ranging from fundamental concepts in molecular and surface science to practical applications in biotechnology, materials engineering, and electronics.

Chapter 1, written by Kazue Kurihara, explores the behavior of molecular structures at solid–liquid interfaces through the lens of surface forces measurements. This foundational discussion introduces readers to the techniques used to study nanoscale interactions and molecular architectures in complex environments—critical knowledge for developing surface-based nanodevices and materials.

Chapter 2, by Suzanne P. Jarvis, focuses on adhesion at the nanoscale, examining the fundamental forces that govern how materials stick at the atomic and molecular levels. This chapter is particularly important for understanding the principles behind nanolithography, nanoimprinting, and biomimetic surface design.

In Chapter 3, Keith J. Stine and Brian G. Moore take readers into the world of Langmuir monolayers. They describe the basic science of these single-molecule-thick films, along with their application in nanotechnology, particularly in areas such as biosensors, membrane mimics, and nano-coatings.

Chapter 4, by Claudio Nicolini, V. Erokhin, and M. K. Ram, transitions into the industrial applications of nanotechnology by detailing supramolecular organic layer engineering. This chapter highlights how ordered organic films can be customized for electronic, optical, and biofunctional applications at the nanoscale, linking academic science to real-world industrial innovation.

Chapter 5, authored by Bernd Tieke, Karl-Ulrich Fulda, and Achim Kampes, discusses the creation of mono- and multilayers of spherical polymer particles using Langmuir–Blodgett and self-assembly techniques. These methods allow precise control over particle arrangement, which is critical in developing photonic crystals, sensor platforms, and microstructured surfaces.

Chapter 6, by Lei Xu and Miquel Salmeron, dives into advanced imaging and analysis techniques, focusing on wetting and capillary phenomena at the nanoscale. Using Scanning Polarization Force Microscopy, the authors provide insights into nanoscale liquid-solid interactions and how they impact the behavior of soft materials and surfaces.

In Chapter 7, Martin E. R. Shanahan and Alain Carré continue the exploration of capillary phenomena, this time emphasizing the deformation of soft materials at the nanometer level. This chapter is particularly relevant to researchers in soft matter physics and biomaterials, offering experimental insights into how capillary forces can shape or distort nano-objects.

Chapter 8, contributed by Marie-Paule Pileni, introduces the concept of two- and three-dimensional superlattices—periodic structures composed of nanocrystals or nanoparticles. The synthesis, self-organization, and collective physical properties of these superlattices are explored, providing a bridge between individual nanoparticles and bulk material behavior.

In Chapter 9, Uwe B. Sleytr, Margit Sára, Dietmar Pum, and Bernhard Schuster present an in-depth examination of two-dimensional protein crystals, also known as S-layers. These naturally occurring nanostructures are explored for their potential in molecular nanotechnology and nanobiotechnology, with applications ranging from biomolecular templating to nano-patterning.

Chapter 10, by Christof M. Niemeyer, shifts the focus to DNA as a material in nanobiotechnology. The chapter covers how DNA can serve not just as a genetic molecule but also as a programmable building block for nanoscale devices and assemblies.

In Chapter 11, Vladimir S. Trubetskoy and Jon A. Wolff examine self-assembled DNA/polymer complexes, investigating how nucleic acids interact with synthetic polymers to form nanostructures with potential for gene delivery, diagnostics, and targeted therapy.

Chapter 12, by Nir Dotan, Noa Cohen, Ori Kalid, and Amihay Freeman, delves deeper into supramolecular assemblies of biological macromolecules. These structures, formed through non-covalent interactions, are foundational to biological nanotechnology and have implications for drug design, synthetic biology, and tissue engineering.

In Chapter 13, Vincenzo Turco Liveri introduces reversed micelles as unique nanometer-scale solvent environments. These self-assembled structures provide confined reaction spaces, useful in studying molecular interactions, catalysis, and nanomaterial synthesis in nonpolar solvents.

Chapter 14, by Frank Caruso, discusses the engineering of core-shell particles and hollow capsules. These nanostructures are increasingly used in targeted drug delivery, diagnostics, and encapsulation technologies, thanks to their controlled geometry and tunable surface properties.

Chapter 15, by Bruce R. Locke, examines electro-transport phenomena in hydrophilic nanostructured materials. Understanding ionic movement in such materials is key for the development of membranes, sensors, and energy storage systems such as batteries and fuel cells.

In Chapter 16, Kwong-Yu Chan continues the discussion on electrochemical behavior, focusing on the role of electrolytes in nanostructures. This chapter underscores the importance of nanoscale confinement and surface area in influencing ionic conductivity and electrochemical reactions.

Chapter 17, the final chapter, by Syed Qutubuddin and Xiaoan Fu, covers the synthesis and material properties of polymer–clay nanocomposites. These materials combine the flexibility and processability of polymers with the mechanical strength and thermal stability of clay nanoparticles, offering solutions in packaging, automotive parts, and barrier technologies.

The book concludes with a comprehensive index, allowing for quick reference and navigation through the diverse topics discussed.

Overall, this volume serves as an authoritative guide for researchers, engineers, and students interested in the frontiers of nanoscience. It integrates theory with practical approaches across physics, chemistry, biology, and engineering to demonstrate how nanoscale phenomena are reshaping modern technology. Through its multidisciplinary approach, it bridges the gap between molecular science and large-scale industrial applications, making it a valuable resource for advancing both fundamental research and innovation in nanotechnology.

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