Synchrotron Techniques in Interfacial Chemistry covers the structure of the electrode--solution interface and surface films, theory of X-ray scattering at surfaces and interfaces, synchrotron radiation instrumentation, surface X-ray diffraction, X-ray reflectivity, X-ray absorption spectroscopy (EXAFS and XANES), standing wave techniques, and IR spectroscopy. The use of each technique in the study of electrochemical problems is illustrated.
Synchrotron Techniques in Interfacial Chemistry covers the structure of the electrode--solution interface and surface films, theory of X-ray scatterin...
Synchrotron Techniques in Interfacial Chemistry covers the structure of the electrode--solution interface and surface films, theory of X-ray scattering at surfaces and interfaces, synchrotron radiation instrumentation, surface X-ray diffraction, X-ray reflectivity, X-ray absorption spectroscopy (EXAFS and XANES), standing wave techniques, and IR spectroscopy. The use of each technique in the study of electrochemical problems is illustrated.
Synchrotron Techniques in Interfacial Chemistry covers the structure of the electrode--solution interface and surface films, theory of X-ray scatterin...
Electrochemistry is one of the oldest branches of Physical Chemistry. Having its foundations in the work of Faraday, Arrhenius and others, it evolved from the study of transport in electrolyte solutions to that of electrode kinetics. Kinetic methods are inherently unable to identify unequivocally the species involved in a reaction. Therefore, beginning in the 70s many spectroscopic and diffraction techniques were applied to the study of the electrode-electrolyte interface, in order to identify intermediary reaction species, and even the spatial arrangement of atoms or molecules at the...
Electrochemistry is one of the oldest branches of Physical Chemistry. Having its foundations in the work of Faraday, Arrhenius and others, it evolved ...
In spite of considerable efforts over the years to understand and combat materials degradation via corrosion processes, many challenges still remain both in the theoretical understanding of the phenomena and in seeking pratical solutions to the perennial problem. Progress has been slow due to the complexity of the processes and the systems involved. Fortunately, in recent years there has been a renaissance in the development of new electrochemical and optical techniques, as well as advances in instrumentation, which have greatly aided our quest to gain insight into the complex mechanisms...
In spite of considerable efforts over the years to understand and combat materials degradation via corrosion processes, many challenges still remain b...
