Electrochemical engineering is the branch of chemical engineering dealing with the technological applications of electrochemical phenomena, such as electrosynthesis of chemicals, electrowinning and refining of metals, flow batteries and fuel cells, surface modification by electrodeposition, electrochemical separations and corrosion. This discipline is an overlap between

electrochemistry Electrochemistry is the branch of physical chemistry concerned with the relationship between electrical potential difference, as a measurable and quantitative phenomenon, and identifiable chemical change, with the potential difference as an outco ...

and

chemical engineering Chemical engineering is an engineering field which deals with the study of operation and design of chemical plants as well as methods of improving production. Chemical engineers develop economical commercial processes to convert raw materials int ...

. According with the

IUPAC The International Union of Pure and Applied Chemistry (IUPAC ) is an international federation of National Adhering Organizations working for the advancement of the chemical sciences, especially by developing nomenclature and terminology. It is ...

, the term ''electrochemical engineering'' is reserved for electricity intensive processes for industrial or energy storage applications, and should not be confused with ''applied electrochemistry'', which comprises small batteries, amperometric sensors, microfluidic devices, microelectrodes, solid-state devices, voltammetry at disc electrodes, etc. More than 6% of the electricity is consumed by large-scale electrochemical operations in the US.

Scope

Electrochemical engineering combines the study of heterogeneous charge transfer at electrode/electrolyte interphases with the development of practical materials and processes. Fundamental considerations include electrode materials and the kinetics of redox species. The development of the technology involves the study of the electrochemical reactors, their potential and current distribution, mass transport conditions, hydrodynamics, geometry and components as well as the quantification of its overall performance in terms of reaction yield, conversion efficiency, and energy efficiency. Industrial developments require further reactor and process design, fabrication methods, testing and product development. Electrochemical engineering considers current distribution, fluid flow, mass transfer, and the kinetics of the electro reactions in order to design efficient electrochemical reactors. Most electrochemical operations are performed in filter-press reactors with parallel plate electrodes or, less often, in stirred tanks with rotating cylinder electrodes. Fuel cell and flow battery stacks are types of filter-press reactors. Most of them are continuous operations.

History

Cell room of a chlorine-caustic soda plant

This branch of engineering emerged gradually from chemical engineering as electrical power sources became available in the mid 19th century.

Michael Faraday Michael Faraday (; 22 September 1791 – 25 August 1867) was an English scientist who contributed to the study of electromagnetism and electrochemistry. His main discoveries include the principles underlying electromagnetic inducti ...

described his laws of electrolysis in 1833, relating for the first time the amount of electrical charge and converted mass. In 1886

Charles Martin Hall Charles Martin Hall (December 6, 1863 – December 27, 1914) was an American inventor, businessman, and chemist. He is best known for his invention in 1886 of an inexpensive method for producing aluminum, which became the first metal to atta ...

developed a cheap electrochemical process for the extraction of aluminium from its ore in molten salts, constituting the first true large-scale electrochemical industry. Later,

Hamilton Castner Hamilton Young Castner (September 11, 1858 – October 11, 1899) was an American industrial chemist. Biography He was born in Brooklyn, New York and educated at the Brooklyn Polytechnic Institute, then at the Columbia University School of Min ...

improved the process aluminium manufacturing and devised the electrolysis of brine in large mercury cells for the production of chlorine and caustic soda, effectively founding the chlor-alkali industry with Karl Kellner in 1892. The next year, Paul L. Hulin patented filter-press type electrochemical cells in France.

Charles Frederick Burgess Charles Frederick Burgess (January 5, 1873 – February 13, 1945) was an American chemist and engineer. He was founder of the University of Wisconsin-Madison department of Chemical Engineering in 1905, and was a pioneer in the development of e ...

developed the electrolytic refining of iron ca. 1904 and later ran a successful battery company. Burgess published one of the first texts on the field in 1920. During the first three decades of the 20th century, industrial electrochemistry followed an empirical approach. After the Second World War, interest focused towards the fundaments of electrochemical reactions. Among other developments, the

potentiostat A potentiostat is the electronic hardware required to control a three electrode cell and run most electroanalytical experiments. A ''Bipotentiostat'' and ''polypotentiostat'' are potentiostats capable of controlling two working electrodes and ...

(1937) enabled such studies. A critical advance was provided by the work of

Carl Wagner Carl Wilhelm Wagner (May 25, 1901 – December 10, 1977) was a German Physical chemist. He is best known for his pioneering work on Solid-state chemistry, where his work on oxidation rate theory, counter diffusion of ions and defect chemistry ...

and

Veniamin Levich Veniamin Grigorievich (Benjamin) Levich (russian: Вениами́н Григо́рьевич Ле́вич; 30 March 1917 in Kharkiv, Ukraine – 19 January 1987 in Englewood, New Jersey, United States) was a Soviet dissident, internationally pro ...

in 1962 who linked the hydrodynamics of a flowing electrolyte towards a rotating disc electrode with the mass transport control of the electrochemical reaction through a rigorous mathematical treatment. The same year, Wagner described for the first time "The Scope of Electrochemical Engineering" as a separated discipline from a physicochemical perspective. During 60s and 70s Charles W. Tobias, who is regarded as the "father of electrochemical engineering" by the Electrochemical Society, was concerned with ionic transport by diffusion, migration, and convection, exact solutions of potential and current distribution problems, conductance in heterogeneous media, quantitative description of processes in porous electrodes. Also in the 60s, John Newman pioneered the study of many of the physicochemical laws that govern electrochemical systems, demonstrating how complex electrochemical processes could be analysed mathematically to correctly formulate and solve problems associated with batteries, fuel cells, electrolyzers and related technologies. In Switzerland, Norbert Ibl contributed with experimental and theoretical studies of mass transfer and potential distribution in electrolyses, especially at porous electrodes. Fumio Hine carried out equivalent developments in Japan. Several individuals, including Kuhn, Kreysa, Rousar, Fleischmann, Alkire, Coeuret, Pletcher and Walsh established many other training centers and, with their colleagues, developed important experimental and theoretical methods of study. Currently, the main tasks of electrochemical engineering consist in the development of efficient, safe and sustainable technologies for the production of chemicals, metal recovery, remediation and decontamination technologies as well as the design of fuel cells, flow batteries and industrial electrochemical reactors. The history of electrochemical engineering has been summarised by Wendt, Lapicque, and Stankovic.

Applications

Electrochemical engineering is applied in industrial

water electrolysis Electrolysis of water, also known as electrochemical water splitting, is the process of using electricity to decompose water into oxygen and hydrogen gas by electrolysis. Hydrogen gas released in this way can be used as hydrogen fuel, or remi ...

, electrolysis, electrosynthesis, electroplating, fuel cells,

flow batteries A flow battery, or redox flow battery (after reduction–oxidation), is a type of electrochemical cell where chemical energy is provided by two chemical components Solution (chemistry), dissolved in liquids that are pumped through the system on ...

, decontamination of industrial effluents, electrorefining, electrowinning, etc. The main example of an electrolysis based process is the

Chloralkali process The chloralkali process (also chlor-alkali and chlor alkali) is an industrial process for the electrolysis of sodium chloride (NaCl) solutions. It is the technology used to produce chlorine and sodium hydroxide (caustic soda), which are commodit ...

for production of caustic soda and chlorine. Other inorganic chemicals produced by electrolysis include: *

Ammonium persulfate Ammonium persulfate (APS) is the inorganic compound with the formula (NH4)2S2O8. It is a colourless (white) salt that is highly soluble in water, much more so than the related potassium salt. It is a strong oxidizing agent that is used as a catalys ...

Chlorine Chlorine is a chemical element with the symbol Cl and atomic number 17. The second-lightest of the halogens, it appears between fluorine and bromine in the periodic table and its properties are mostly intermediate between them. Chlorine i ...

* Electrowinning * Fluorine *

Hydrogen peroxide Hydrogen peroxide is a chemical compound with the formula . In its pure form, it is a very pale blue liquid that is slightly more viscous than water. It is used as an oxidizer, bleaching agent, and antiseptic, usually as a dilute solution (3%� ...

* Manganese dioxide *

Ozone Ozone (), or trioxygen, is an inorganic molecule with the chemical formula . It is a pale blue gas with a distinctively pungent smell. It is an allotrope of oxygen that is much less stable than the diatomic allotrope , breaking down in the lo ...

Potassium dichromate Potassium dichromate, , is a common inorganic chemical reagent, most commonly used as an oxidizing agent in various laboratory and industrial applications. As with all hexavalent chromium compounds, it is acutely and chronically harmful to health ...

Potassium permanganate Potassium permanganate is an inorganic compound with the chemical formula KMnO4. It is a purplish-black crystalline salt, that dissolves in water as K+ and , an intensely pink to purple solution. Potassium permanganate is widely used in the c ...

Sodium chlorate Sodium chlorate is an inorganic compound with the chemical formula Na ClO3. It is a white crystalline powder that is readily soluble in water. It is hygroscopic. It decomposes above 300 °C to release oxygen and leaves sodium chloride. Sever ...

Sodium hypochlorite Sodium hypochlorite (commonly known in a dilute solution as bleach) is an inorganic chemical compound with the formula NaOCl (or NaClO), comprising a sodium cation () and a hypochlorite anion (or ). It may also be viewed as the sodium s ...

Sodium persulfate Sodium persulfate is the inorganic compound with the formula Sodium, Na2Sulfur, S2Oxygen, O8. It is the sodium salt of peroxydisulfuric acid, H2S2O8, an oxidizing agent. It is a white solid that dissolves in water. It is almost non-hygroscopic an ...

Silver nitrate Silver nitrate is an inorganic compound with chemical formula . It is a versatile precursor to many other silver compounds, such as those used in photography. It is far less sensitive to light than the halides. It was once called ''lunar causti ...

White lead White lead is the basic lead carbonate 2PbCO3·Pb(OH)2. It is a complex salt, containing both carbonate and hydroxide ions. White lead occurs naturally as a mineral, in which context it is known as hydrocerussite, a hydrate of cerussite. It was ...

(Basic lead carbonate)

Conventions

The established performance criteria, definitions and nomenclature for electrochemical engineering can be found in Kreysa et al. and an IUPAC report.

Awards

* Castner Medal * Carl Wagner Medal * Vittorio de Nora Award

References

Bibliography

*T.F. Fuller, John N. Harb, ''Electrochemical Engineering'', John Wiley & Sons, 2018. *H. Wright (ed.), ''Electrochemical Engineering: Emerging Technologies and Applications'', Willford Press, 2016. *D. Stolten, B. Emonts, ''Fuel Cell Science and Engineering: Materials, Processes, Systems and Technology'', John Wiley & Sons, 2012. *D.D. Macdonald, P. Schmuki (eds.), ''Electrochemical Engineering'', in ''Encyclopedia of Electrochemistry'', Vol. 5, Wiley-VCH, 2007. *J. Newman, K.E. Thomas-Alyea, ''Electrochemical Systems'', 3rd ed., John Wiley & Sons, Hoboken NJ, 2004. (1st ed. 1973). *V.M. Schmidt, ''Elektrochemische Verfahrenstechnik'', Wiley-VCH, 2003. *H. Pütter, ''Industrial Electroorganic Chemistry'', in ''Organic Electrochemistry'', 4th ed., H. Lund, O. Hammerich (eds.), Marcel Dekker, New York, 2001. *F.C. Walsh, ''Un Primer Curso de Ingeniería Electroquímica'', Editorial Club Universitario, Alicante, España, 2000. *M.P. Grotheer, ''Electrochemical Processing, Inorganic'', in ''Kirk-Othmer Encyclopedia of Chemical Technology'', 5th ed., Vol. 9, P. 618, John Wiley & Sons, 2000. *H. Wendt, G. Kreysa, ''Electrochemical Engineering: Science and Technology in Chemical and Other Industries'', Springer, Berlin 1999. *R.F. Savinell, ''Tutorials in Electrochemical Engineering - Mathematical Modeling'', Pennington, The Electrochemical Society, 1999. *A. Geoffrey, ''Electrochemical Engineering Principles'', Prentice Hall, 1997. *F. Goodrige, K. Scott ''Electrochemical Process Engineering - A Guide to the Design of Electrolytic Plant'', Plenum Press, New York & London, 1995. *J. Newman, R.E. White (eds.), ''Proceedings of the Douglas N. Bennon Memorial Symposium. Topics in Electrochemical Engineering'', The Electrochemical Society, Proceedings Vol. 94-22, 1994. *F. Lapicque, A. Storck, A.A. Wragg, ''Electrochemical Engineering and Energy'', Springer, 1994. *F.C. Walsh, ''A First Course in Electrochemical Engineering'', The Electrochemical Consultancy, Romsey UK, 1993. *F. Coeuret, A. Storck, ''Eléments de Génie Électrochimique'', 2nd ed., Éditions TEC et DOC / Lavoisier, Paris, 1993. (1st ed. 1984) *F. Coeuret, ''Introducción a la Ingeniería Electroquímica'', Editorial Reverté, Barcelona, 1992. *K. Scott, ''Electrochemical Reaction Engineering'', Academic Press, London, 1991. *G. Prentice, ''Electrochemical Engineering Principles'', Prentice Hall, 1991. *D. Pletcher, F.C. Walsh, ''Industrial Electrochemistry'', 2nd ed., Chapman and Hall, London, 1990. *J.D. Genders, D. Pletcher, ''Electrosynthesis - From Laboratory, to Pilot, to Production'', The Electrosynthesis Company, New York, 1990. *M.I. Ismail, ''Electrochemical Reactors Their Science and Technology - Part A: Fundamentals, Electrolysers, Batteries, and Fuel Cells'', Elsevier, Amsterdam, 1989. *T.R. Beck, ''Industrial Electrochemical Processes'', in ''Techniques of Electrochemistry'', E. Yeager, A.J. Salkind (eds.), Wiley, New York, 1987. *E. Heitz, G. Kreysa, ''Principles of Electrochemical Engineering'', John Wiley & Sons, 1986. *I. Roušar, A. Kimla, K. Micka, ''Electrochemical Engineering'', Elsevier, Amsterdam, 1986. *T.Z. Fahidy, ''Principles of Electrochemical Reactor Analysis'', Elsevier, Amsterdam, 1985. *F. Hine, ''Electrode Processes and Electrochemical Engineering'', Springer, Boston, 1985. *R.E. White, (ed.), ''Electrochemical Cell Design'', Springer, 1984. *P. Horsman, B.E. Conway, S. Sarangapani (eds.), ''Comprehensive Treatise of Electrochemistry. Vol. 6 Electrodics: Transport'', Plenum Press, New York, 1983. *D. Pletcher, ''Industrial Electrochemistry'', 1st ed., Chapman and Hall, London, 1982. *J.O’M. Bockris, B.E. Conway, E. Yeager, R.E. White, (eds.) ''Comprehensive Treatise of Electrochemistry. Vol. 2: Electrochemical Processing'', Plenum Press, New York, 1981. *D.J. Pickett, ''Electrochemical Reactor Design'', 2nd ed., Elsevier, Amsterdam, 1979. *P. Gallone, ''Trattato di Ingegneria Elettrochimica'', Tamburini, Milan, 1973. *A. Kuhn, ''Industrial Electrochemical Processes'', Elsevier, Amsterdam, 1971. *C.L. Mantell, ''Electrochemical Engineering'', 4th ed., McGraw-Hill, New York, 1960. *C.L. Mantell, ''Industrial Electrochemistry'', 2nd ed., McGraw-Hill, New York, 1940. *C.F. Burgess, H.B. Pulsifer, B.B. Freud, ''Applied Electrochemistry and Metallurgy'', American Technical Society, Chicago, 1920. *A.J. Hale, ''The Manufacture of Chemicals by Electrolysis'', Van Nostrand Co., New York, 1919.

External links

Working Party on Electrochemical Engineering - WPEESCI Castner Medal on Industrial Electrochemistry
* ttps://www.electrochem.org/de-nora-award ECS Vittorio de Nora Awardbr>IEEE H.H. Dow Memorial Student Achievement Award
{{Engineering fields Electrochemistry Chemical engineering Chemical processes * Hydrogen production Industrial processes Industrial gases