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{{Short description|American chemist (1912–2004)}}
{{redirect|Herbert Charles Brown|the Australian public servant|Herbert Charles Brown (public servant)}}
{{for|the Australian public servant|Herbert Charles Brown (public servant)}}
{{Infobox scientist
{{Infobox scientist
|name = Herbert C. Brown
| name = Herbert C. Brown
|image = Herbert_C._Brown.png
| image = Herbert_C._Brown.png
|birth_name=Herbert Brovarnik
| birth_name = Herbert Brovarnik
|birth_date = May 22, 1912
| birth_date = May 22, 1912
|birth_place = [[London]], [[England]], UK
| birth_place = [[London]], [[England]], UK
|death_date = {{death date and age|2004|12|19|1912|05|22}}
| death_date = {{death date and age|2004|12|19|1912|05|22}}
|death_place = [[Lafayette, Indiana]], US
| death_place = [[Lafayette, Indiana]], US
|nationality = American
| nationality = American
|field = [[Chemistry]]
| field = [[Chemistry]]
|work_institutions = [[University of Chicago]], <br> [[Purdue University]]
| work_institutions = [[University of Chicago]], <br> [[Purdue University]]
|alma_mater = [[University of Chicago]]
| alma_mater = [[University of Chicago]]
|doctoral_advisor = [[Hermann Irving Schlesinger]]
| doctoral_advisor = [[Hermann Irving Schlesinger]]
|doctoral_students =
| doctoral_students =
|known_for = [[Organoboranes]]
| known_for = [[Organoboranes]]
|author_abbrev_bot =
| author_abbrev_bot =
|author_abbrev_zoo =
| author_abbrev_zoo =
| prizes = [[Centenary Prize]] {{small|(1955)}}<br>[[William H. Nichols Medal]] {{small|(1959)}}<br>[[National Medal of Science]] {{small|(1969)}}<br> [[Elliott Cresson Medal]] {{small|(1978)}}<br> [[Nobel Prize for Chemistry]] {{small|(1979)}}<br> [[Priestley Medal]] {{small|(1981)}}<br>[[Perkin Medal]] {{small|(1982)}}<ref name="SCI Perkin Medal">{{cite web|title=SCI Perkin Medal|url=https://www.sciencehistory.org/sci-perkin-medal|website=[[Science History Institute]]|access-date=24 March 2018|url-status=live|archive-url=https://web.archive.org/web/20180202130738/https://www.sciencehistory.org/sci-perkin-medal|archive-date=2 February 2018|date=2016-05-31}}</ref><br> [[American Institute of Chemists Gold Medal|AIC Gold Medal]] {{small|(1985)}}<br>[[NAS Award in Chemical Sciences]] <small>(1987)</small>
|influences =
| religion =
|influenced = [[Akira Suzuki (chemist)|Akira Suzuki]]<br>[[Ei-ichi Negishi]]
| footnotes =
| prizes = [[National Medal of Science]] {{small|(1969)}}<br> [[Elliott Cresson Medal]] {{small|(1978)}}<br> [[Nobel Prize for Chemistry]] {{small|(1979)}}<br> [[Priestley Medal]] {{small|(1981)}}<br>[[Perkin Medal]] {{small|(1982)}}<ref name="SCI Perkin Medal">{{cite web|title=SCI Perkin Medal|url=https://www.sciencehistory.org/sci-perkin-medal|website=[[Science History Institute]]|accessdate=24 March 2018|deadurl=no|archiveurl=https://web.archive.org/web/20180202130738/https://www.sciencehistory.org/sci-perkin-medal|archivedate=2 February 2018|df=|date=2016-05-31}}</ref><br> [[American Institute of Chemists Gold Medal|AIC Gold Medal]] {{small|(1985)}}<br>[[NAS Award in Chemical Sciences]] <small>(1987)</small>
| spouse = Sarah Baylen (1937–2005; his death; 1 child)
|religion =
|footnotes =
|spouse=Sarah Baylen (1937–2004; his death; 1 child)
}}
}}
'''Herbert Charles Brown''' (May 22, 1912 – December 19, 2004) was an English-born American chemist and recipient of the 1979 [[Nobel Prize in Chemistry]] for his work with [[organoborane]]s.
'''Herbert Charles Brown''' (May 22, 1912 – December 19, 2004) was an American chemist and recipient of the 1979 [[Nobel Prize in Chemistry]] for his work with [[organoborane]]s.


==Life and career==
==Life and career==
Brown was born '''Herbert Brovarnik''' in [[London]], to Ukrainian Jewish immigrants from [[Zhitomir]], Pearl (''[[née]]'' Gorinstein) and Charles Brovarnik, a hardware store manager and carpenter.<ref>{{cite book|url=https://books.google.com/books?id=jEy67gEvIuMC&pg=PA605|title=Nobel Laureates in Chemistry, 1901-1992|first=James K.|last=Laylin|date=30 October 1993|publisher=Chemical Heritage Foundation|via=Google Books|isbn=9780841226906}}</ref> His family moved to [[Chicago]] in June 1914, when he was two years old.<ref name="Nobel-bio">{{cite web | author = Wilhelm Odelberg | title = Herbert C. Brown: The Nobel Prize in Chemistry 1979 | work = Les Prix Nobel | publisher = [[Nobel Foundation]] | year = 1979 | url = http://nobelprize.org/nobel_prizes/chemistry/laureates/1979/brown-autobio.html | accessdate = 2007-08-27 | deadurl = no | archiveurl = https://web.archive.org/web/20070819114912/http://nobelprize.org/nobel_prizes/chemistry/laureates/1979/brown-autobio.html | archivedate = 2007-08-19 | df = }}</ref><ref name="Negishi">{{cite web | last = Negishi | first = Ei-Ichi | title = Herbert Charles Brown | publisher = National Academy of Sciences | date = 2008 | url = http://www.nasonline.org/publications/biographical-memoirs/memoir-pdfs/brown-herbert-c.pdf | deadurl = no | archiveurl = https://web.archive.org/web/20150910021245/http://www.nasonline.org/publications/biographical-memoirs/memoir-pdfs/brown-herbert-c.pdf | archivedate = 2015-09-10 | df = }}</ref> Brown attended [[Crane Junior College]] in Chicago, where he met Sarah Baylen, whom he would later marry. The college was under threat of closing, and Brown and Baylen transferred to [[Wilbur Wright College|Wright Junior College]].<ref name="Negishi"/> In 1935 he left Wright Junior College and that autumn entered the [[University of Chicago]], completed two years of studies in three quarters, and earned a [[Bachelor of Science|B.S.]] in 1936.<ref name="Nobel-bio"/> That same year, he became a naturalized [[United States citizen]].<ref name="NNDB">{{cite web | title = Herbert C. Brown | work = Notable Names Database | publisher = Soylent Communications | url = http://www.nndb.com/people/625/000100325/ | accessdate = 2007-08-27 | deadurl = no | archiveurl = https://web.archive.org/web/20070930072227/http://www.nndb.com/people/625/000100325/ | archivedate = 2007-09-30 | df = }}</ref> On February 6, 1937, Brown married Baylen, the person he credits with making him interested in hydrides of [[boron]], a topic related to the work in which he, together with [[Georg Wittig]], won the Nobel prize in Chemistry in 1979.<ref name="Nobel-bio"/> Two years after starting graduate studies, he earned a [[Doctor of Philosophy|Ph.D.]] in 1938, also from the University of Chicago.
Brown was born '''Herbert Brovarnik''' in [[London]], to Ukrainian [[Jews|Jewish]] immigrants from [[Zhitomir]], Pearl (''[[née]]'' Gorinstein) and Charles Brovarnik, a hardware store manager and carpenter.<ref>{{cite book|url=https://books.google.com/books?id=jEy67gEvIuMC&pg=PA605|title=Nobel Laureates in Chemistry, 1901-1992|first=James K.|last=Laylin|date=30 October 1993|publisher=Chemical Heritage Foundation|via=Google Books|isbn=9780841226906}}</ref> His family moved to [[Chicago]] in June 1914, when he was two years old.<ref name="Nobel-bio">{{cite web | author = Wilhelm Odelberg | title = Herbert C. Brown: The Nobel Prize in Chemistry 1979 | work = Les Prix Nobel | publisher = [[Nobel Foundation]] | year = 1979 | url = http://nobelprize.org/nobel_prizes/chemistry/laureates/1979/brown-autobio.html | access-date = 2007-08-27 | url-status = live | archive-url = https://web.archive.org/web/20070819114912/http://nobelprize.org/nobel_prizes/chemistry/laureates/1979/brown-autobio.html | archive-date = 2007-08-19 }}</ref><ref name="Negishi">{{cite web | last = Negishi | first = Ei-Ichi | title = Herbert Charles Brown | publisher = National Academy of Sciences | date = 2008 | url = http://www.nasonline.org/publications/biographical-memoirs/memoir-pdfs/brown-herbert-c.pdf | url-status = live | archive-url = https://web.archive.org/web/20150910021245/http://www.nasonline.org/publications/biographical-memoirs/memoir-pdfs/brown-herbert-c.pdf | archive-date = 2015-09-10 }}</ref> Brown attended [[Crane Junior College]] in Chicago, where he met Sarah Baylen, whom he would later marry. The college was under threat of closing, and Brown and Baylen transferred to [[Wilbur Wright College|Wright Junior College]].<ref name="Negishi"/> In 1935 he left Wright and that autumn entered the [[University of Chicago]], completing two years of studies in three quarters to earn a [[Bachelor of Science|B.S.]] in 1936.<ref name="Nobel-bio"/> That same year, he became a naturalized [[United States citizen]],<ref name="NNDB">{{cite web | title = Herbert C. Brown | work = Notable Names Database | publisher = Soylent Communications | url = http://www.nndb.com/people/625/000100325/ | access-date = 2007-08-27 | url-status = live | archive-url = https://web.archive.org/web/20070930072227/http://www.nndb.com/people/625/000100325/ | archive-date = 2007-09-30 }}</ref> and began graduate studies at Chicago. On February 6, 1937, Brown married Baylen, whom he would later credit with sparking an interest in [[hydrides]] of [[boron]] that would eventually lead to the work for which he, together with [[Georg Wittig]], would be awarded the Nobel prize in Chemistry in 1979,<ref name="Nobel-bio"/> and the following year received his degree as [[Doctor of Philosophy|Ph.D.]].


Unable to find a position in industry, he decided to accept a postdoctoral position. This became the beginning of his academic career. He became an instructor at the University of Chicago in 1939, and held the position for four years before moving to [[Wayne University]] in Detroit as an assistant professor. In 1946, he was promoted to associate professor. After being denied tenure at the University of Chicago, he became a [[professor]] of [[inorganic chemistry]] at [[Purdue University]] in 1947<ref name="purdue-bio">
Unable to find a position in industry, he decided to accept a [[Postdoctoral researcher|postdoctoral]] position, beginning his academic career. He became an instructor at Chicago in 1939, and held the position for four years before moving to [[Wayne University]] in [[Detroit]] as an [[assistant professor]]. In 1946, he was promoted to [[associate professor]], and the following year became a [[professor]] of [[inorganic chemistry]] at [[Purdue University]] in 1947<ref name="purdue-bio">
{{cite web
{{cite web
|title = Biography of Herbert C. Brown
|title = Biography of Herbert C. Brown
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|year = 2001
|year = 2001
|url = http://www.chem.purdue.edu/people/HCBrown/default.asp
|url = http://www.chem.purdue.edu/people/HCBrown/default.asp
|accessdate = 2007-08-27
|access-date = 2007-08-27
|deadurl = no
|url-status = live
|archiveurl = https://web.archive.org/web/20080326234703/http://www.chem.purdue.edu/people/HCBrown/default.asp
|archive-url = https://web.archive.org/web/20080326234703/http://www.chem.purdue.edu/people/HCBrown/default.asp
|archivedate = 2008-03-26
|archive-date = 2008-03-26
}}</ref> and joined the Beta Nu chapter of [[Alpha Chi Sigma]] there in 1960.<ref name="AXE-HallOfFame">{{cite web
|df =
}}</ref> and joined the Beta Nu Chapter of [[Alpha Chi Sigma]] there in 1960.<ref name="AXE-HallOfFame">
{{cite web
| title = Alpha Chi Sigma Hall of Fame
| title = Alpha Chi Sigma Hall of Fame
| publisher = Alpha Chi Sigma Fraternity
| publisher = Alpha Chi Sigma Fraternity
| url = http://www.alphachisigma.org/NetCommunity/Page.aspx?pid=268&srcid=273
| url = http://www.alphachisigma.org/NetCommunity/Page.aspx?pid=268&srcid=273
| accessdate = 2008-01-07
| access-date = 2008-01-07
}}</ref> He held the position of [[Professor Emeritus]] from 1978 until his death in 2004.<ref name="Nobel-bio"/> The ''Herbert C. Brown Laboratory of Chemistry'' was named after him on Purdue University's campus. He was an honorary member of the [[International Academy of Science]].
}}{{Dead link|date=March 2023 |bot=InternetArchiveBot |fix-attempted=yes }}</ref> He held the position of [[Professor Emeritus]] from 1978 until his death in 2004.<ref name="Nobel-bio"/> The ''Herbert C. Brown Laboratory of Chemistry'' was named after him on Purdue University's campus. He was an honorary member of the International Academy of Science, Munich.


During [[World War II]], while working with [[Hermann Irving Schlesinger]], Brown discovered a method for producing [[sodium borohydride]] (NaBH<sub>4</sub>), which can be used to produce [[borane]]s, compounds of [[boron]] and [[hydrogen]]. His work led to the discovery of the first general method for producing asymmetric pure [[enantiomer]]s. The elements found as initials of his name [[hydrogen|H]], [[carbon|C]] and [[boron|B]] were his working field.
During [[World War II]], while working with [[Hermann Irving Schlesinger]], Brown discovered a method for producing [[sodium borohydride]] (NaBH<sub>4</sub>), which can be used to produce [[borane]]s, compounds of [[boron]] and [[hydrogen]]. His work led to the discovery of the first general method for producing asymmetric pure [[enantiomer]]s. The elements found as initials of his name [[hydrogen|H]], [[carbon|C]] and [[boron|B]] were his working field.


In 1969, he was awarded the [[National Medal of Science]].<ref>{{cite web|url=https://www.nsf.gov/od/nms/recip_details.cfm?recip_id=59|title=The President's National Medal of Science: Recipient Details - NSF - National Science Foundation|author=|date=|website=www.nsf.gov|deadurl=no|archiveurl=https://web.archive.org/web/20121015220111/http://www.nsf.gov/od/nms/recip_details.cfm?recip_id=59|archivedate=2012-10-15|df=}}</ref>
In 1969, he was awarded the [[National Medal of Science]].<ref>{{cite web|url=https://www.nsf.gov/od/nms/recip_details.cfm?recip_id=59|title=The President's National Medal of Science: Recipient Details - NSF - National Science Foundation|website=www.nsf.gov|url-status=live|archive-url=https://web.archive.org/web/20121015220111/http://www.nsf.gov/od/nms/recip_details.cfm?recip_id=59|archive-date=2012-10-15}}</ref>


Brown was quick to credit his wife Sarah with supporting him and allowing him to focus on creative efforts by handling finances, maintaining the house and yard, etc. According to Brown, after receiving the Nobel prize in [[Stockholm]], he carried the medal and she carried the US$100,000 award.
Brown was quick to credit his wife Sarah with supporting him and allowing him to focus on creative efforts by handling finances, maintaining the house and yard, etc. According to Brown, after receiving the Nobel prize in [[Stockholm]], he carried the medal and she carried the US$100,000 award.


In 1971, he received the Golden Plate Award of the [[Academy of Achievement|American Academy of Achievement]].<ref>{{cite web|title= Golden Plate Awardees of the American Academy of Achievement |website=www.achievement.org|publisher=[[American Academy of Achievement]]|url=https://achievement.org/our-history/golden-plate-awards/#science-exploration}}</ref>
He was inducted into the [[Alpha Chi Sigma]] Hall of Fame in 2000.<ref>{{cite web|url=https://www.alphachisigma.org/|title=Alpha Chi Sigma Fraternity|author=|date=|website=alphachisigma.org|deadurl=no|archiveurl=https://web.archive.org/web/20171207192148/https://www.alphachisigma.org/|archivedate=2017-12-07|df=}}</ref>


He was inducted into the [[Alpha Chi Sigma]] Hall of Fame in 2000.<ref>{{cite web|url=https://www.alphachisigma.org/|title=Alpha Chi Sigma Fraternity|website=alphachisigma.org|url-status=live|archive-url=https://web.archive.org/web/20171207192148/https://www.alphachisigma.org/|archive-date=2017-12-07}}</ref>
He died December 19, 2004, at a [[hospital]] in [[Lafayette, Indiana]] after a [[myocardial infarction|heart attack]]. His wife died May 29, 2005, aged 89.

He died December 19, 2004, at a [[hospital]] in [[Lafayette, Indiana]] after a [[myocardial infarction|heart attack]].<ref>{{cite web|url=https://www.nytimes.com/2004/12/21/obituaries/herbert-c-brown-92-dies-chemist-won-nobel-for-boron-work.html|title=Herbert C. Brown, 92, Dies; Chemist Won Nobel for Boron Work|date=December 21, 2004|author=Kenneth Chang|website=The New York Times|access-date=January 7, 2022}}</ref> His wife died May 29, 2005, aged 89.


==Research==
==Research==
[[File:Borane & Diborane.jpg|thumb|Borane, BH<sub>3</sub>, is a gaseous compound that is only present at high temperatures. It dimerises to form diborane, B<sub>2</sub>H<sub>6</sub>. Diborane has a pair of [[Three-center two-electron bond|three-center two-electron bonds.]]]] As a doctoral student at the [[University of Chicago]], Herbert Brown studied the reactions of [[diborane]], B<sub>2</sub>H<sub>6</sub>. [[Hermann Irving Schlesinger|Hermann Irving Schlesinger's]] laboratory at the University of Chicago was one of two laboratories that prepared diborane. It was a rare compound that was only prepared in small quantities. Schlesinger was researching the reactions of diborane to understand why the simplest hydrogen-boron compound is B<sub>2</sub>H<sub>6</sub> instead of BH<sub>3</sub>.<ref name="Lecture">{{cite web |url=http://www.chem.purdue.edu/hcbrown/nobel.pdf |title=Archived copy |accessdate=2014-05-14 |deadurl=yes |archiveurl=https://web.archive.org/web/20140809033952/http://www.chem.purdue.edu/hcbrown/nobel.pdf |archivedate=2014-08-09 |df= }}</ref>
[[File:Borane & Diborane.jpg|thumb|Borane, BH<sub>3</sub>, is a gaseous compound that is only present at high temperatures. It dimerises to form diborane, B<sub>2</sub>H<sub>6</sub>. Diborane has a pair of [[Three-center two-electron bond|three-center two-electron bonds.]]]] As a doctoral student at the [[University of Chicago]], Herbert Brown studied the reactions of [[diborane]], B<sub>2</sub>H<sub>6</sub>. [[Hermann Irving Schlesinger|Hermann Irving Schlesinger's]] laboratory at the University of Chicago was one of two laboratories that prepared diborane. It was a rare compound that was only prepared in small quantities. Schlesinger was researching the reactions of diborane to understand why the simplest hydrogen-boron compound is B<sub>2</sub>H<sub>6</sub> instead of BH<sub>3</sub>.<ref name="Lecture">{{cite web |url=http://www.chem.purdue.edu/hcbrown/nobel.pdf |title=Archived copy |access-date=2014-05-14 |url-status=dead |archive-url=https://web.archive.org/web/20140809033952/http://www.chem.purdue.edu/hcbrown/nobel.pdf |archive-date=2014-08-09 }}</ref>


[[File:Ketone diborane reduction.png|thumb|A general reaction between diborane and a [[ketone]]]] When Brown started his own research, he observed the reactions of diborane with [[aldehydes]], [[ketones]], [[esters]], and [[acid chlorides]]. He discovered that diborane reacts with aldehydes and ketones to produce dialkoxyboranes, which are [[hydrolysis|hydrolyzed]] by water to produce [[alcohols]]. Until this point, organic chemists did not have an acceptable method of [[redox|reducing]] [[carbonyls]] under mild conditions. Yet Brown’s Ph.D. thesis published in 1939 received little interest. Diborane was too rare to be useful as a synthetic reagent.<ref name="Lecture"/>
[[File:Ketone diborane reduction.png|thumb|A general reaction between diborane and a [[ketone]]]] When Brown started his own research, he observed the reactions of diborane with [[aldehydes]], [[ketones]], [[esters]], and [[acid chlorides]]. He discovered that diborane reacts with aldehydes and ketones to produce dialkoxyboranes, which are [[hydrolysis|hydrolyzed]] by water to produce [[alcohols]]. Until this point, organic chemists did not have an acceptable method of [[redox|reducing]] [[carbonyls]] under mild conditions. Yet Brown's Ph.D. thesis published in 1939 received little interest. Diborane was too rare to be useful as a synthetic reagent.<ref name="Lecture"/>


In 1939, Brown became the research assistant in Schlesinger’s laboratory. In 1940, they began to research volatile, low molecular weight uranium compounds for the [[National Defense Research Committee]]. Brown and Schlesinger successfully synthesized volatile uranium(IV) borohydride, which had a molecular weight of 298. The laboratory was asked to provide a large amount of the product for testing, but diborane was in short supply. They discovered that it could be formed by reacting [[lithium hydride]] with [[boron trifluoride]] in [[ethyl ether]], allowing them to produce the chemical in larger quantities. This success was met with several new problems. Lithium hydride was also in short supply, so Brown and Schlesinger needed to find a procedure that would allow them to use [[sodium hydride]] instead. They discovered that sodium hydride and [[methyl borate]] reacted to produce [[sodium trimethoxyborohydride]], which was viable as a substitute for the lithium hydride.<ref name="Lecture"/>
In 1939, Brown became the research assistant in Schlesinger's laboratory. In 1940, they began to research volatile, low molecular weight uranium compounds for the [[National Defense Research Committee]]. Brown and Schlesinger successfully synthesized volatile uranium(IV) borohydride, which had a molecular weight of 298. The laboratory was asked to provide a large amount of the product for testing, but diborane was in short supply. They discovered that it could be formed by reacting [[lithium hydride]] with [[boron trifluoride]] in [[ethyl ether]], allowing them to produce the chemical in larger quantities. This success was met with several new problems. Lithium hydride was also in short supply, so Brown and Schlesinger needed to find a procedure that would allow them to use [[sodium hydride]] instead. They discovered that sodium hydride and [[methyl borate]] reacted to produce [[sodium trimethoxyborohydride]], which was viable as a substitute for the lithium hydride.<ref name="Lecture"/>


Soon they were informed that there was no longer a need for uranium borohydride, but it appeared that sodium borohydride could be useful in generating [[hydrogen]]. They began to look for a cheaper synthesis and discovered that adding methyl borate to sodium hydride at 250° produced sodium borohydride and sodium methoxide. When [[acetone]] was used in an attempt to separate the two products, it was discovered that sodium borohydride reduced the acetone.<ref name="Lecture"/>
Soon they were informed that there was no longer a need for uranium borohydride, but it appeared that sodium borohydride could be useful in generating [[hydrogen]]. They began to look for a cheaper synthesis and discovered that adding methyl borate to sodium hydride at 250° produced sodium borohydride and sodium methoxide. When [[acetone]] was used in an attempt to separate the two products, it was discovered that sodium borohydride reduced the acetone.<ref name="Lecture"/>
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Sodium borohydride is a mild [[reducing agent]] that works well in reducing aldehydes, ketones, and acid chlorides. Lithium aluminum hydride is a much more powerful reducing agent that can reduce almost any [[functional group]]. When Brown moved to [[Purdue University]] in 1947, he worked to find stronger [[borohydrides]] and milder [[aluminum hydride]]s that would provide a spectrum of reducing agents. The team of researchers at Purdue discovered that changing the metal ion of the borohydride to [[lithium]], [[magnesium]], or [[aluminum]] increases the reducing ability. They also found that introducing [[alkoxy]] substituents to the aluminum hydride decreases the reducing ability. They successfully developed a full spectrum of reducing agents.<ref name="Lecture"/>
Sodium borohydride is a mild [[reducing agent]] that works well in reducing aldehydes, ketones, and acid chlorides. Lithium aluminum hydride is a much more powerful reducing agent that can reduce almost any [[functional group]]. When Brown moved to [[Purdue University]] in 1947, he worked to find stronger [[borohydrides]] and milder [[aluminum hydride]]s that would provide a spectrum of reducing agents. The team of researchers at Purdue discovered that changing the metal ion of the borohydride to [[lithium]], [[magnesium]], or [[aluminum]] increases the reducing ability. They also found that introducing [[alkoxy]] substituents to the aluminum hydride decreases the reducing ability. They successfully developed a full spectrum of reducing agents.<ref name="Lecture"/>


[[File:Hydroboration-Oxidation.jpg|thumb|In [[hydroboration-oxidation]], the [[hydroxyl|OH group]] adds to the less-substituted carbon in the double bond.]] While researching these reducing agents, Brown’s coworker, Dr. B. C. Subba Rao, discovered an unusual reaction between sodium borohydride and [[ethyl oleate]]. The borohydride added hydrogen and boron to the carbon-carbon [[double bond]] in the ethyl oleate. The organoborane product could then be [[redox|oxidized]] to form an alcohol.<ref name="Lecture"/> This two-step reaction is now called [[hydroboration-oxidation]] and is a reaction that converts [[alkenes]] into anti-Markovnikov alcohols. [[Markovnikov's rule]] states that, in adding hydrogen and a [[halide]] or [[hydroxyl]] group to a carbon-carbon double bond, the hydrogen is added to the less-substituted carbon of the bond and the hydroxyl or halide group is added to the more-substituted carbon of the bond. In hydroboration-oxidation, the opposite addition occurs.<ref>{{cite web|url=http://www.chem.ucla.edu/harding/IGOC/H/hydroboration_oxidation_reaction.html|title=Illustrated Glossary of Organic Chemistry - Hydroboration-oxidation reaction |author= |date= |website=www.chem.ucla.edu |deadurl=no|archiveurl=https://web.archive.org/web/20140515084824/http://www.chem.ucla.edu/harding/IGOC/H/hydroboration_oxidation_reaction.html|archivedate=2014-05-15|df=}}</ref>
[[File:Hydroboration-Oxidation.jpg|thumb|In [[hydroboration-oxidation]], the [[hydroxyl|OH group]] adds to the less-substituted carbon in the double bond.]] While researching these reducing agents, Brown's coworker, Dr. B. C. Subba Rao, discovered an unusual reaction between sodium borohydride and [[ethyl oleate]]. The borohydride added hydrogen and boron to the carbon-carbon [[double bond]] in the ethyl oleate. The organoborane product could then be [[redox|oxidized]] to form an alcohol.<ref name="Lecture"/> This two-step reaction is now called [[hydroboration-oxidation]] and is a reaction that converts [[alkenes]] into anti-Markovnikov alcohols. [[Markovnikov's rule]] states that, in adding hydrogen and a [[halide]] or [[hydroxyl]] group to a carbon-carbon double bond, the hydrogen is added to the less-substituted carbon of the bond and the hydroxyl or halide group is added to the more-substituted carbon of the bond. In hydroboration-oxidation, the opposite addition occurs.<ref>{{cite web|url=http://www.chem.ucla.edu/harding/IGOC/H/hydroboration_oxidation_reaction.html|title=Illustrated Glossary of Organic Chemistry - Hydroboration-oxidation reaction |website=www.chem.ucla.edu |url-status=live|archive-url=https://web.archive.org/web/20140515084824/http://www.chem.ucla.edu/harding/IGOC/H/hydroboration_oxidation_reaction.html|archive-date=2014-05-15}}</ref>


==See also==
==See also==
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==External links==
==External links==
*{{Nobelprize}}
*[https://www.nobelprize.org/chemistry/laureates/1979/brown-autobio.html Herbert Brown biography] at the [[Nobel Foundation]] from ''Les Prix Nobel'', 1979
*[http://pubs.acs.org/cen/news/8251/8251brown12_23.html Herbert Brown obituary] in [[Chemical & Engineering News]]
*[http://pubs.acs.org/cen/news/8251/8251brown12_23.html Herbert Brown obituary] in [[Chemical & Engineering News]]
*[https://www.usatoday.com/tech/science/2004-12-21-hbrown-obit_x.htm Herbert Brown obituary] in [[USA Today]]
*[https://www.usatoday.com/tech/science/2004-12-21-hbrown-obit_x.htm Herbert Brown obituary] in [[USA Today]]
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{{Nobel Prize in Chemistry Laureates 1976-2000}}
{{Nobel Prize in Chemistry Laureates 1976-2000}}
{{1979 Nobel Prize winners}}
{{Winners of the National Medal of Science|physical}}
{{Winners of the National Medal of Science|physical}}


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[[Category:1912 births]]
[[Category:1912 births]]
[[Category:2004 deaths]]
[[Category:2004 deaths]]
[[Category:English Jews]]
[[Category:Nobel laureates in Chemistry]]
[[Category:British Nobel laureates]]
[[Category:American Nobel laureates]]
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Latest revision as of 15:24, 30 November 2024

Herbert C. Brown
Born
Herbert Brovarnik

May 22, 1912
DiedDecember 19, 2004(2004-12-19) (aged 92)
NationalityAmerican
Alma materUniversity of Chicago
Known forOrganoboranes
Spouse(s)Sarah Baylen (1937–2005; his death; 1 child)
AwardsCentenary Prize (1955)
William H. Nichols Medal (1959)
National Medal of Science (1969)
Elliott Cresson Medal (1978)
Nobel Prize for Chemistry (1979)
Priestley Medal (1981)
Perkin Medal (1982)[1]
AIC Gold Medal (1985)
NAS Award in Chemical Sciences (1987)
Scientific career
FieldsChemistry
InstitutionsUniversity of Chicago,
Purdue University
Doctoral advisorHermann Irving Schlesinger

Herbert Charles Brown (May 22, 1912 – December 19, 2004) was an American chemist and recipient of the 1979 Nobel Prize in Chemistry for his work with organoboranes.

Life and career

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Brown was born Herbert Brovarnik in London, to Ukrainian Jewish immigrants from Zhitomir, Pearl (née Gorinstein) and Charles Brovarnik, a hardware store manager and carpenter.[2] His family moved to Chicago in June 1914, when he was two years old.[3][4] Brown attended Crane Junior College in Chicago, where he met Sarah Baylen, whom he would later marry. The college was under threat of closing, and Brown and Baylen transferred to Wright Junior College.[4] In 1935 he left Wright and that autumn entered the University of Chicago, completing two years of studies in three quarters to earn a B.S. in 1936.[3] That same year, he became a naturalized United States citizen,[5] and began graduate studies at Chicago. On February 6, 1937, Brown married Baylen, whom he would later credit with sparking an interest in hydrides of boron that would eventually lead to the work for which he, together with Georg Wittig, would be awarded the Nobel prize in Chemistry in 1979,[3] and the following year received his degree as Ph.D..

Unable to find a position in industry, he decided to accept a postdoctoral position, beginning his academic career. He became an instructor at Chicago in 1939, and held the position for four years before moving to Wayne University in Detroit as an assistant professor. In 1946, he was promoted to associate professor, and the following year became a professor of inorganic chemistry at Purdue University in 1947[6] and joined the Beta Nu chapter of Alpha Chi Sigma there in 1960.[7] He held the position of Professor Emeritus from 1978 until his death in 2004.[3] The Herbert C. Brown Laboratory of Chemistry was named after him on Purdue University's campus. He was an honorary member of the International Academy of Science, Munich.

During World War II, while working with Hermann Irving Schlesinger, Brown discovered a method for producing sodium borohydride (NaBH4), which can be used to produce boranes, compounds of boron and hydrogen. His work led to the discovery of the first general method for producing asymmetric pure enantiomers. The elements found as initials of his name H, C and B were his working field.

In 1969, he was awarded the National Medal of Science.[8]

Brown was quick to credit his wife Sarah with supporting him and allowing him to focus on creative efforts by handling finances, maintaining the house and yard, etc. According to Brown, after receiving the Nobel prize in Stockholm, he carried the medal and she carried the US$100,000 award.

In 1971, he received the Golden Plate Award of the American Academy of Achievement.[9]

He was inducted into the Alpha Chi Sigma Hall of Fame in 2000.[10]

He died December 19, 2004, at a hospital in Lafayette, Indiana after a heart attack.[11] His wife died May 29, 2005, aged 89.

Research

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Borane, BH3, is a gaseous compound that is only present at high temperatures. It dimerises to form diborane, B2H6. Diborane has a pair of three-center two-electron bonds.

As a doctoral student at the University of Chicago, Herbert Brown studied the reactions of diborane, B2H6. Hermann Irving Schlesinger's laboratory at the University of Chicago was one of two laboratories that prepared diborane. It was a rare compound that was only prepared in small quantities. Schlesinger was researching the reactions of diborane to understand why the simplest hydrogen-boron compound is B2H6 instead of BH3.[12]

A general reaction between diborane and a ketone

When Brown started his own research, he observed the reactions of diborane with aldehydes, ketones, esters, and acid chlorides. He discovered that diborane reacts with aldehydes and ketones to produce dialkoxyboranes, which are hydrolyzed by water to produce alcohols. Until this point, organic chemists did not have an acceptable method of reducing carbonyls under mild conditions. Yet Brown's Ph.D. thesis published in 1939 received little interest. Diborane was too rare to be useful as a synthetic reagent.[12]

In 1939, Brown became the research assistant in Schlesinger's laboratory. In 1940, they began to research volatile, low molecular weight uranium compounds for the National Defense Research Committee. Brown and Schlesinger successfully synthesized volatile uranium(IV) borohydride, which had a molecular weight of 298. The laboratory was asked to provide a large amount of the product for testing, but diborane was in short supply. They discovered that it could be formed by reacting lithium hydride with boron trifluoride in ethyl ether, allowing them to produce the chemical in larger quantities. This success was met with several new problems. Lithium hydride was also in short supply, so Brown and Schlesinger needed to find a procedure that would allow them to use sodium hydride instead. They discovered that sodium hydride and methyl borate reacted to produce sodium trimethoxyborohydride, which was viable as a substitute for the lithium hydride.[12]

Soon they were informed that there was no longer a need for uranium borohydride, but it appeared that sodium borohydride could be useful in generating hydrogen. They began to look for a cheaper synthesis and discovered that adding methyl borate to sodium hydride at 250° produced sodium borohydride and sodium methoxide. When acetone was used in an attempt to separate the two products, it was discovered that sodium borohydride reduced the acetone.[12]

Sodium borohydride is a mild reducing agent that works well in reducing aldehydes, ketones, and acid chlorides. Lithium aluminum hydride is a much more powerful reducing agent that can reduce almost any functional group. When Brown moved to Purdue University in 1947, he worked to find stronger borohydrides and milder aluminum hydrides that would provide a spectrum of reducing agents. The team of researchers at Purdue discovered that changing the metal ion of the borohydride to lithium, magnesium, or aluminum increases the reducing ability. They also found that introducing alkoxy substituents to the aluminum hydride decreases the reducing ability. They successfully developed a full spectrum of reducing agents.[12]

In hydroboration-oxidation, the OH group adds to the less-substituted carbon in the double bond.

While researching these reducing agents, Brown's coworker, Dr. B. C. Subba Rao, discovered an unusual reaction between sodium borohydride and ethyl oleate. The borohydride added hydrogen and boron to the carbon-carbon double bond in the ethyl oleate. The organoborane product could then be oxidized to form an alcohol.[12] This two-step reaction is now called hydroboration-oxidation and is a reaction that converts alkenes into anti-Markovnikov alcohols. Markovnikov's rule states that, in adding hydrogen and a halide or hydroxyl group to a carbon-carbon double bond, the hydrogen is added to the less-substituted carbon of the bond and the hydroxyl or halide group is added to the more-substituted carbon of the bond. In hydroboration-oxidation, the opposite addition occurs.[13]

See also

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References

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  1. ^ "SCI Perkin Medal". Science History Institute. 2016-05-31. Archived from the original on 2 February 2018. Retrieved 24 March 2018.
  2. ^ Laylin, James K. (30 October 1993). Nobel Laureates in Chemistry, 1901-1992. Chemical Heritage Foundation. ISBN 9780841226906 – via Google Books.
  3. ^ a b c d Wilhelm Odelberg (1979). "Herbert C. Brown: The Nobel Prize in Chemistry 1979". Les Prix Nobel. Nobel Foundation. Archived from the original on 2007-08-19. Retrieved 2007-08-27.
  4. ^ a b Negishi, Ei-Ichi (2008). "Herbert Charles Brown" (PDF). National Academy of Sciences. Archived (PDF) from the original on 2015-09-10.
  5. ^ "Herbert C. Brown". Notable Names Database. Soylent Communications. Archived from the original on 2007-09-30. Retrieved 2007-08-27.
  6. ^ "Biography of Herbert C. Brown". Purdue University. 2001. Archived from the original on 2008-03-26. Retrieved 2007-08-27.
  7. ^ "Alpha Chi Sigma Hall of Fame". Alpha Chi Sigma Fraternity. Retrieved 2008-01-07.[permanent dead link]
  8. ^ "The President's National Medal of Science: Recipient Details - NSF - National Science Foundation". www.nsf.gov. Archived from the original on 2012-10-15.
  9. ^ "Golden Plate Awardees of the American Academy of Achievement". www.achievement.org. American Academy of Achievement.
  10. ^ "Alpha Chi Sigma Fraternity". alphachisigma.org. Archived from the original on 2017-12-07.
  11. ^ Kenneth Chang (December 21, 2004). "Herbert C. Brown, 92, Dies; Chemist Won Nobel for Boron Work". The New York Times. Retrieved January 7, 2022.
  12. ^ a b c d e f "Archived copy" (PDF). Archived from the original (PDF) on 2014-08-09. Retrieved 2014-05-14.{{cite web}}: CS1 maint: archived copy as title (link)
  13. ^ "Illustrated Glossary of Organic Chemistry - Hydroboration-oxidation reaction". www.chem.ucla.edu. Archived from the original on 2014-05-15.
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