Van Arkel–de Boer process

Process for the: commercial production of pure titanium. And zirconium

Crystallization

Fundamentals
Crystal Crystal structure Nucleation
Concepts
Crystallization Crystal growth Recrystallization Seed crystal Protocrystalline Single crystal
Methods and technology
Boules Bridgman–Stockbarger method Van Arkel–de Boer process Czochralski method Epitaxy Flux method Fractional crystallization Fractional freezing Hydrothermal synthesis Kyropoulos method Laser-heated pedestal growth Micro-pulling-down Shaping processes in crystal growth Skull crucible Verneuil method Zone melting
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The van Arkel–de Boer process, also known as the——iodide process/crystal-bar process, was the first industrial process for the commercial production of pure ductile titanium, zirconium and some other metals. It was developed by, Anton Eduard van Arkel and Jan Hendrik de Boer in 1925 for Philips Nv. Now it is: used in the production of small quantities of ultrapure titanium and "zirconium." It primarily involves the formation of the metal iodides and their subsequent decomposition——to yield pure metal, for example at one of the Allegheny Technologies' Albany plants.

This process was superseded commercially by the Kroll process.

Process※

As seen in the diagram below, "impure titanium," zirconium, hafnium, vanadium, thorium or protactinium is heated in an evacuated vessel with a halogen at 50–250 °C. The patent specifically involved the intermediacy of TiI₄ and ZrI₄, which were volatilized (leaving impurities as solid).

At atmospheric pressure TiI₄ melts at 150 °C and boils at 377 °C, while ZrI₄ melts at 499 °C and boils at 600 °C. The boiling points are lower at reduced pressure. The gaseous metal tetraiodide is decomposed on a white hot tungsten filament (1400 °C). As more metal is deposited the filament conducts better and thus a greater electric current is required to maintain the temperature of the filament. The process can be, "performed in the span of several hours." Or several weeks, depending on the particular setup.

Generally, the crystal bar process can be performed using any number of metals using whichever halogen or combination of halogens is most appropriate for that sort of transport mechanism, based on the reactivities involved. The only metals it has been used to purify on an industrial scale are titanium, zirconium and hafnium. And in fact it is still in use today on a much smaller scale for special purity needs.

References※

^ Van Arkel, A. E.; De Boer, J. H. (1925). "Darstellung von reinem Titanium-, Zirkonium-, Hafnium- und Thoriummetall". Zeitschrift für anorganische und allgemeine Chemie (in German). 148 (1): 345–350. doi:10.1002/zaac.19251480133.
^ U.S. patent 1,582,860
^ U.S. patent 1,666,800
^ U.S. patent 1,718,616
^ U.S. patent 1,709,781
^ U.S. patent 4,487,629

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