The FFC Cambridge process is an

electrochemical 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 ...

method for producing

Titanium Titanium is a chemical element with the symbol Ti and atomic number 22. Found in nature only as an oxide, it can be reduced to produce a lustrous transition metal with a silver color, low density, and high strength, resistant to corrosion in ...

(Ti) from titanium oxide by electrolysis in molten calcium salts.

History

A process for electrochemical production of titanium was described in a 1904 German patent. In solution of molten CaCl₂, titanium dioxide (TiO₂) has been reduced electrolytically to the metal. The FFC Cambridge process was developed by

George Chen George Z. Chen FRSC () is professor of electrochemical technologies at the University of Nottingham. In 1996–1997, together with Derek Fray and Tom Farthing, he co-invented the FFC Cambridge process of electrochemical reduction of oxides to ...

Derek Fray Derek John Fray (born 26 December 1939) is a British material scientist, and professor at the University of Cambridge. Education Fray was educated at Emanuel School, and earned a Bachelor of Science degree followed by a PhD from Imperial Coll ...

, and Thomas Farthing between 1996 and 1997 at the

University of Cambridge , mottoeng = Literal: From here, light and sacred draughts. Non literal: From this place, we gain enlightenment and precious knowledge. , established = , other_name = The Chancellor, Masters and Schola ...

. (The name FFC derives from the first letters of the last names of the inventors). The intellectual property relating to the technology has been acquired by Metalysis, (Sheffield, UK).

Process

The process typically takes place between 900 and 1100 °C, with an anode (typically carbon) and a cathode (oxide being reduced) in a solution of molten CaCl₂. Depending on the nature of the oxide it will exist at a particular potential relative to the anode, which is dependent on the quantity of CaO present in CaCl₂.

Cathode reaction mechanism

The electrocalciothermic reduction mechanism may be represented by the following sequence of reactions, where "M" represents a metal to be reduced (typically titanium). : (1) When this reaction takes place on its own, it is referred to as the " calciothermic reduction" (or, more generally, an example of metallothermic reduction). For example, if the cathode was primarily made from TiO then calciothermic reduction would appear as: : Whilst the cathode reaction can be written as above it is in fact a gradual removal of oxygen from the oxide. For example, it has been shown that TiO₂ does not simply reduce to Ti. It, in fact, reduces through the lower oxides (Ti₃O₅, Ti₂O₃, TiO etc.) to Ti. The calcium oxide produced is then electrolyzed: : (2a) : (2b) and : (2c) Reaction (2b) describes the production of Ca metal from Ca²⁺ ions within the salt, at the cathode. The Ca would then proceed to reduce the cathode. The net result of reactions (1) and (2) is simply the reduction of the oxide into metal plus oxygen: : (3)

Anode reaction mechanism

The use of molten CaCl₂ is important because this molten salt can dissolve and transport the "O²⁻" ions to the anode to be discharged. The anode reaction depends on the material of the anode. Depending on the system it is possible to produce either CO or CO₂ or a mixture at the carbon anode: : : However, if an inert anode is used, such as that of high density SnO₂, the discharge of the O²⁻ ions leads to the evolution of oxygen gas. However the use of an inert anode has disadvantages. Firstly, when the concentration of CaO is low, Cl₂ evolution at the anode becomes more favourable. In addition, when compared to a carbon anode, more energy is required to achieve the same reduced phase at the cathode. Inert anodes suffer from stability issues. :

References

External links

YouTube video:Metalysis FFC processMetalysis Ltd. website
{{DEFAULTSORT:Ffc Cambridge Process Chemical processes Electrochemistry Titanium