Hartmut Wendt Book order

Electrochemical engineering diverges significantly from traditional chemical engineering due to the unique physics and physical chemistry involved in systems like electrolyzers, batteries, and fuel cells. Key distinctions include the critical roles of interfacial charge transfer, current density distributions, and mass transfer limitations in liquid electrolytes. This field has evolved with a focus on high-level mathematics to model various configurations accurately. However, it often overlooks the chemical aspects integral to electrochemical technology, highlighting a gap in interdisciplinary understanding.

Electrochemical Engineering sounds very much like chemical engineering, but the chemists, electro chemists, material scientists and whoever else comes into touch with technical electrochemical systems very soon gets the feeling, that chemical engineering wisdom will not get them very far in enhancing their un derstanding and helping them to solve their problems with technical electro chemical devices. Indeed not only the appearance of but also the physics and physical chemistry in electrochemical reactors - electrolyzers, batteries or fuel cells and others - are quite different from that of normal chemical reactors. Next to interfacial charge transfer and current density distributions is the relatively high importance of mass transfer and its hindrance in liquid electrolytes which distinguishes electrolyzers from chemical reactors. Therefore electrochemical engineering science became a science branch which at first developed with little reference to chemical engineering treating the relevant topics on a high mathe maticallevel. This has led to a certain perfection, which today - in principl- allows us to model almost any desired electrolyzer or cell configuration with nu merical methods to a degree and precision which satisfies the highest demands. This is classical chemical engineering stuff, which, however, neglects the chem ical side of electrochemical technology.