Details

Preface<br> <br> ATTACHMENT OF ORGANIC LAYERS TO MATERIALS SURFACES BY REDUCTION OF DIAZONIUM SALTS <br> A Brief Survey of the Chemistry and Electrochemistry of Diazonium Salts <br> The Different Methods that Permit Grafting of Diazonium Salts <br> The Different Substrates, Diazonium Salts, and Solvents that Can Be Used <br> Evidence for the Presence of a Bond between the Substrate and the Organic Layer <br> From Monolayers to Multilayers <br> Structure and Formation of Multilayers <br> Conclusion <br> <br> ARYL-SURFACE BONDING: A DENSITY FUNCTIONAL THEORY (DFT) SIMULATION APPROACH <br> Introduction <br> Density Functional Theory <br> Bonding between Aryl and Various Substrates <br> Summary and Outlook <br> <br> PATTERNED MOLECULAR LAYERS ON SURFACES <br> Methods Based on Scanning Probe Lithography <br> Methods Based on Soft Lithography <br> Methods Based on Lithography <br> Methods Based on Surface-Directed Patterning <br> Summary and Conclusions <br> <br> ANALYTICAL METHODS FOR THE CHARACTERIZATION OF ARYL LAYERS <br> Introduction <br> Scanning Probe Microscopies <br> UV-VIS Spectroscopy: Transmission, Reflection, and Ellipsometry <br> IR Spectroscopy <br> Raman Spectroscopy and Surface-Enhanced Raman Scattering (SERS) <br> X-ray Photoelectron Spectroscopy (XPS) <br> X-ray Standing Waves (XSW) <br> Rutherford Backscattering <br> Time of Flight Secondary Ion Mass Spectroscopy <br> Electrochemistry <br> Contact Angle Measurements <br> Conclusion <br> <br> MODIFICATION OF NANO-OBJECTS BY ARYL DIAZONIUM SALTS <br> Introduction <br> Electrochemical Modification of Nano-objects by Reduction of Diazonium Salts <br> Chemical Modification of Nano-objects by Reduction of Diazonium Salts <br> Summary and Conclusions <br> <br> POLYMER GRAFTING TO ARYL DIAZONIUM-MODIFIED MATERIALS: METHODS AND APPLICATIONS <br> Introduction <br> Methods for Grafting Coupling Agents from Aryl Diazonium Compounds <br> Grafting Macromolecules to Surfaces through Aryl Layers <br> Adhesion of Polymers to Surfaces through Aryl Layers <br> Conclusion <br> <br> GRAFTING POLYMER FILMS ONTO MATERIAL SURFACES: THE ONE-STEP REDOX PROCESSES <br> Cathodic Electrografting (CE) in an Organic Medium <br> Surface Electroinitiated Emulsion Polymerization (SEEP) Chemical Grafting via Chemical Redox Activation (Graftfast/TM) <br> Summary and Conclusions <br> <br> ELECTROGRAFTING OF CONDUCTIVE OLIGOMERS AND POLYMERS <br> Introduction <br> Conjugated Oligomers and Polymers <br> Surface Grafting Based on Electroreduction of Diazonium Salts <br> Polyphenylene and Oligophenylene-Tethered Surface Prepared by the Diazonium Reduction of Aniline or 4-Substituted Aniline <br> n-Doping and Conductance Switching of Grafted Biphenyl, Terphenyl, Nitro-biphenyl and 4-Nitroazobenzene Mono- and Multilayers <br> p-Doping and Conductance Switching of Grafted Oligo- Phenylthiophene or Oligothiophene Mono- and Multilayers <br> p-Doping and Conductance Switching of Grafted Oligoaniline Mono- and Multilayers <br> Conclusion and Outlook <br> <br> THE USE OF ARYL DIAZONIUM SALTS IN THE FABRICATION OF BIOSENSORS AND CHEMICAL SENSORS <br> Introduction <br> The Important Features of Aryl Diazonium Salts with Regard to Sensing <br> Sensors and Biosensors Fabricated Using Aryl Diazonium Salts <br> Conclusions <br> <br> DIAZONIUM COMPOUNDS IN MOLECULAR ELECTRONICS <br> Introduction <br> Fabrication of Molecular Junctions Using Diazonium Reagents Electronic Performance of Diazonium-Derived Molecular Junctions <br> Summary and Outlook <br> <br> ELECTRONIC PROPERTIES OF SI SURFACES MODIFIED BY ARYL DIAZONIUM COMPOUNDS <br> Introduction <br> Experimental Techniques to Characterize Electronic Properties of Si Surfaces in Solutions <br> Conclusion and Outlook <br> <br> NON-DIAZONIUM ORGANIC AND ORGANOMETALLIC COUPLING AGENTS FOR SURFACE MODIFICATION <br> Amines <br> Arylhydrazines <br> Aryltriazenes <br> Alcohols <br> Grignard Reagents <br> Onium Salts <br> Alkyl Halides <br> Conclusion <br> <br> VARIOUS ELECTROCHEMICAL STRATEGIES FOR GRAFTING ELECTRONIC FUNCTIONAL MOLECULES TO SILICON <br> Introduction <br> Architecture of Hybrid Devices <br> Electrografting of Monolayers to Si Negative Differential Resistance Effect in a Monolayer Electrografted Using a Diazonium Complex <br> Dielectric Monolayers Electrografted Using Silanes <br> Molecular Diodes Based on C60/Porphyrin-Derivative Bilayers <br> Memory Effect in TPP-C11 Monolayers Electrografted Using a C=C Linker <br> Summary <br> <br> PATENTS AND INDUSTRIAL APPLICATIONS OF ARYL DIAZONIUM SALTS AND OTHER COUPLING AGENTS <br> Introduction <br> Patents <br> Industrial Applications <br> Conclusion <br>

Mohamed M. Chehimi is Research Director at the National Center for Scientific Research (CNRS) in France and the leader of the Surface & Interface research group at ITODYS Laboratory of the University Paris Diderot, where he obtained his PhD in physical organic chemistry in 1988 and finished his Habilitation in 1995. He has authored over 200 scientific publications and has received the Honorary Medal from the Polymer Institute (Slovak Academy of Sciences, Slovakia) for long term and efficient international cooperation on surface and interface aspects of nanocomposites in 2008. His main research interests are aryl diazonium coupling agents, reactive and functional ultrathin polymer films via surface polymerization or "click" chemistry, carbon/polymer composites for the uptake of heavy metals, molecularly imprinted polymer-based sensors, clay/polymer nanocomposites and films, powders, latex particles, and nanocomposites of conductive polypyrrole.

Diazonium compounds are employed as a new class of coupling agents to link polymers, biomacromolecules, and other species (e. g. metallic nanoparticles) to the surface of materials. The resulting high performance materials show improved chemical and physical properties and find widespread applications. The advantage of aryl diazonium salts compared to other surface modifiers lies in their ease of preparation, rapid (electro)reduction, large choice of reactive functional groups, and strong aryl-surface covalent bonding.<br> <br> This unique book summarizes the current knowledge of the surface and interface chemistry of aryl diazonium salts. It covers fundamental aspects of diazonium chemistry together with theoretical calculations of surface-molecule bonding, analytical methods used for the characterization of aryl layers, as well as important applications in the field of electrochemistry, nanotechnology, biosensors, polymer coatings and materials science. Furthermore, information on other surface modifiers (amines, silanes, hydrazines, iodonium salts) is included. This collection of 14 self-contained chapters constitutes a valuable book for PhD students, academics and industrial researchers working on this hot topic.<br>

SG