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Bayer worked in the textile industry in Saint Petersburg, where aluminum hydroxide was used to help affix dye to the cotton.[4] While working he made two important discoveries regarding processing steps that helped separate the Bayer process from that of Le Chatelier. In 1888, Bayer found that by using a pure seed of aluminum hydroxide, a crystalline precipitate formed that was more economical than that obtained by Le Chatelier.[3] In 1892, Bayer discovered that by using an [[Autoclave (industrial)|autoclave]], or a pressure leaching vessel, in combination with an [[Sodium hydroxide|NaOH]] leachant the process resulted in a very pure [[sodium aluminate]] solution that could be used for his precipitation step that he discovered previously. Both steps are widely used today but have been improved upon as technology has evolved. After discovery, Bayer worked as a startup consultant for alumina manufacturing around Europe. Bayer returned to Austria in 1894 to start an alumina factory but was unable to secure enough capital to fully fund the project.
Bayer worked in the textile industry in Saint Petersburg, where aluminum hydroxide was used to help affix dye to the cotton.[4] While working he made two important discoveries regarding processing steps that helped separate the Bayer process from that of Le Chatelier. In 1888, Bayer found that by using a pure seed of aluminum hydroxide, a crystalline precipitate formed that was more economical than that obtained by Le Chatelier.[3] In 1892, Bayer discovered that by using an [[Autoclave (industrial)|autoclave]], or a pressure leaching vessel, in combination with an [[Sodium hydroxide|NaOH]] leachant the process resulted in a very pure [[sodium aluminate]] solution that could be used for his precipitation step that he discovered previously. Both steps are widely used today but have been improved upon as technology has evolved. After discovery, Bayer worked as a startup consultant for alumina manufacturing around Europe. Bayer returned to Austria in 1894 to start an alumina factory but was unable to secure enough capital to fully fund the project.


Importance to the Aluminum Industry
===Importance to the Aluminum Industry===
Alumina and aluminum production underwent significant changes in processing due to discoveries made by Karl Bayer, [[Charles Martin Hall]], and [[Paul Héroult]]. Hall and Heroult share credit for inventing aluminum electrolysis. The [[Hall–Héroult process|Hall-Heroult method]] is the primary method of producing modern aluminum and requires high purity alumina to produce aluminum.
Alumina and aluminum production underwent significant changes in processing due to discoveries made by Karl Bayer, [[Charles Martin Hall]], and [[Paul Héroult]]. Hall and Heroult share credit for inventing aluminum electrolysis. The [[Hall–Héroult process|Hall-Heroult method]] is the primary method of producing modern aluminum and requires high purity alumina to produce aluminum. The Bayer process produces high purity alumina which is then used in the Hall-Heroult process as the main raw material. In 1900, aluminum was valued at the equivalent of 100 current US dollars, but over the next 50 years decreased in price to approximately 20 current US dollars. This decrease is attributed to the increase in the ease of manufacturing associated with aluminum after Bayer, Hall, and Heroult’s discoveries.




Revision as of 22:02, 12 April 2019


Carl Josef Bayer (also Karl Bayer, March 4, 1847 – October 4, 1904) was an Austrian chemist who invented the Bayer process of extracting alumina from bauxite, essential to this day to the economical production of aluminium.

Bayer had been working in Saint Petersburg to develop a method to provide alumina to the textile industry that used it as a fixing agent in the dyeing of cotton. In 1887, he discovered that aluminium hydroxide precipitated from an alkaline solution which is crystalline and can be filtered and washed more easily than that precipitated from an acid medium by neutralization.[1] In 1888, Bayer developed and patented his four-stage process of extracting alumina from bauxite ore.

In the mid-19th-century, aluminium was so precious that a bar of the metal was exhibited alongside the French Crown Jewels at the Exposition Universelle in Paris 1855.[2] Along with the Hall-Héroult process, Bayer's solution caused the price of aluminum to drop about 80% in 1890 from what it had been in 1854.[3]


Life and Education

Carl Bayer was born (March 4, 1847) in what is currently Poland, but at the time of birth a province in the Austrian Empire known as Silesia.[4] He attended Heidelberg university in Germany where he studied chemistry under Robert Bunsen from 1869-1871, the namesake of the Bunsen burner. At Heidelberg, Bayer received his doctorate degree with a dissertation on the recently discovered metal of indium in 1871.[4] After obtaining his doctorate, Bayer lectured for two years at Technische Hochschule in Bmo, and then left to establish his own research and consulting company.

Personal Life and Education

Carl Bayer was born (March 4, 1847) in the Duchy of Upper and Lower Silesia in the Austrian Empire, which is now Poland.[1] He attended Heidelberg University in Germany where he studied chemistry under Robert Bunsen from 1869-1871, the namesake of the Bunsen burner. At Heidelberg, Bayer received his doctorate degree in 1871 with a dissertation on the chemistry of indium which was discovered recently in 1863.[1] After obtaining his doctorate, Bayer lectured for two years at Technische Hochschule in Brno, and then left to establish his own research company. Bayer then moved to St. Petersburg in 1885 where he flourished as an inventor. At age 45 he married the daughter of a Russian politician, Alma Von Witte and settled in Rietzdorf (modern day Rečica ob Paki, Slovenia). Together they had six children, and in 1904 at the age of 57, Bayer died. His wife would survive him until 1962, when she died at the age of 94.

Aluminum Ore Processing Prior to Bayer

Bauxite was discovered in 1821 by Pierre Berthier and named it after a village named Les Beaux where he found it.[2] To obtain the alumina from the bauxite ore, a process was developed that used acid to dissolve aluminum but resulted in a product that contained large amounts of iron and titanium dissolved within which were difficult to remove. Due to these impurities, the process was not employed for use, but was an approach that was explored. Louis Le Chatelier, in 1855, created a process that produced aluminum hydroxide by heating in sodium carbonate and then leaching.[3] Bubbling through the solution with CO2 precipitated aluminum hydroxide, which when dried, allowed for the recovery of alumina.

Bayer’s Contribution to Aluminum Ore Processing

Bayer worked in the textile industry in Saint Petersburg, where aluminum hydroxide was used to help affix dye to the cotton.[4] While working he made two important discoveries regarding processing steps that helped separate the Bayer process from that of Le Chatelier. In 1888, Bayer found that by using a pure seed of aluminum hydroxide, a crystalline precipitate formed that was more economical than that obtained by Le Chatelier.[3] In 1892, Bayer discovered that by using an autoclave, or a pressure leaching vessel, in combination with an NaOH leachant the process resulted in a very pure sodium aluminate solution that could be used for his precipitation step that he discovered previously. Both steps are widely used today but have been improved upon as technology has evolved. After discovery, Bayer worked as a startup consultant for alumina manufacturing around Europe. Bayer returned to Austria in 1894 to start an alumina factory but was unable to secure enough capital to fully fund the project.

Importance to the Aluminum Industry

Alumina and aluminum production underwent significant changes in processing due to discoveries made by Karl Bayer, Charles Martin Hall, and Paul Héroult. Hall and Heroult share credit for inventing aluminum electrolysis. The Hall-Heroult method is the primary method of producing modern aluminum and requires high purity alumina to produce aluminum. The Bayer process produces high purity alumina which is then used in the Hall-Heroult process as the main raw material. In 1900, aluminum was valued at the equivalent of 100 current US dollars, but over the next 50 years decreased in price to approximately 20 current US dollars. This decrease is attributed to the increase in the ease of manufacturing associated with aluminum after Bayer, Hall, and Heroult’s discoveries.



Sources

  • United States Patent Application 20050238571: Process and apparatus for the production of alumina
  • The History of Aluminum

See also

References

  1. ^ Seetharaman, Seshadri (2014). Treatise on Process Metallurgy Volume 3: Industrial Processes, Part A. United Kingdom: Elsevier. p. 841. ISBN 978-0-08-096988-6.
  2. ^ [1]
  3. ^ "Archived copy" (PDF). Archived from the original (PDF) on 2005-09-29. Retrieved 2006-03-01. {{cite web}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)CS1 maint: archived copy as title (link)
  4. ^ a b Habashi, Fathi (October 2004). "Karl Josef Bayer and his time - Part 2". CIM Bulletin. 1083: 62–66.


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