OCH 213. ADVANCED INORGANIC CHEMISTRY----- BY. MWL. JAPHET MASATU.

F. Albert Cotton

Frank Albert Cotton
Born	April 9, 1930 Philadelphia, PA
Died	February 20, 2007 (aged 76) College Station, TX
Institutions	Texas A&M University
Doctoral advisor	Geoffrey Wilkinson
Notable awards	National Medal of Science, Wolf Prize, Priestley Medal, FRS

Frank Albert Cotton (April 9, 1930 – February 20, 2007)^[1] was an American chemist. He was the W.T. Doherty-Welch Foundation Chair and Distinguished Professor of Chemistry at Texas A&M University. He authored over 1700 scientific articles.^[2] Cotton was recognized for his research on the chemistry of the transition metals.

Contents

• 1 Education
• 2 Independent career
• 3 Pedagogical influence
• 4 Recognition
• 5 Run for ACS presidency
• 6 F.A. Cotton Medal for Excellence in Chemical Research
• 7 Death
• 8 References

Education

Frank Albert Cotton (known as "Al" Cotton, or "F Albert" on publications) was born on April 9, 1930 in Philadelphia, Pennsylvania. He attended local public schools before Drexel University and then Temple University.^[3] After earning his BA degree from Temple in 1951, Cotton pursued a Ph.D. thesis under the guidance of Sir Geoffrey Wilkinson at Harvard where he worked on metallocenes.^[4] He received his Ph.D in 1955.^[5]

Independent career

Following his graduation from Harvard, Cotton began teaching at MIT. In 1961, at thirty-one years of age, he became the youngest person to have received a full professorship at MIT.^[3] His work emphasized both electronic structure and chemical synthesis. He pioneered the study of multiple bonding between transition metal atoms, starting with research on rhenium halides,^[6] and in 1964 identified the quadruple bond in the Re
2Cl2−
8 ion. His work soon focused on other metal-metal bonded species,^[7] elucidating the structure of chromium(II) acetate.
He was an early proponent of single crystal X-ray diffraction as a tool for elucidating the extensive chemistry of metal complexes. Through his studies on clusters, he demonstrated that many exhibited "fluxionality", whereby ligands interchange coordination sites on spectroscopically observable time-scales. He coined the term "hapticity" and the nomenclature that derives from it.
In 1962 he undertook the crystal structure of the Staphylococcal nuclease enzyme,^[8] solved to 2Å resolution in 1969, published in 1971,^[9] and deposited in the Protein Data Bank (PDB code 1SNS) as one of the first dozen protein crystal structures.^[10]
In 1972 Cotton moved to Texas A&M University as the Robert A. Welch Professor of Chemistry. The following year he was named the Doherty-Welch Distinguished Professor of Chemistry. He also served as the director of the university's Laboratory for Molecular Structure and Bonding.^[3][11]

Pedagogical influence

In addition to his research, Cotton taught inorganic chemistry. He authored Chemical Applications of Group Theory.^[12] This text focuses on group theoretical analysis of bonding and spectroscopy.
Among college students, Cotton is perhaps best known as the coauthor of the textbook Advanced Inorganic Chemistry, now in its sixth English edition.^[13][14] Coauthored with his thesis advisor, Sir Geoffrey Wilkinson, and now with coauthors Carlos Murillo and Manfred Bochmann, the textbook is colloquially known as "Cotton and Wilkinson." The text surveys coordination chemistry, cluster chemistry, homogeneous catalysis, and organometallic chemistry.^[3][15]
Cotton served on various editorial boards of scientific journals, including those of the Journal of the American Chemical Society, Inorganic Chemistry, and Organometallics. He chaired the Division of Inorganic Chemistry of the ACS and was an ACS Councillor for five years. He served on the U.S. National Science Board (1986–1998), which oversees the National Science Foundation, and the Scientific and Technical Advisory Committee of Argonne National Laboratory, and the National Research Laboratory Commission of Texas.
Cotton supervised the thesis research of 116 doctoral students^[11] as well as more than 150 postdoctoral associates.^[5]

Recognition

Among the awards Cotton received included the U.S. National Medal of Science in 1982,^[16] the Wolf Prize in 2000; and the Priestley Medal, the American Chemical Society's highest recognition, in 1998.^[11]
In 1995, the Department of Chemistry at Texas A&M along with the local section of the American Chemical Society, inaugurated the annual F.A. Cotton Medal for excellence in chemical research. A second award named in his honor, the F. Albert Cotton Award for Synthetic Inorganic Chemistry,^[17] is presented at the National Meeting of the American Chemical Society each year.^[11]
Cotton was a member of the National Academy of Sciences in the United States, and the corresponding academies in Russia, China, the United Kingdom, France, and Denmark, as well as the American Philosophical Society. He received twenty-nine honorary doctorates.^[11]

Run for ACS presidency

Cotton caused a controversy in his run for President of the American Chemical Society for 1984, wherein he mailed a letter to selected members describing his opponent as “a mediocre industrial chemist”.^[18] Cotton ultimately lost the bid to his opponent Dr. Warren D. Niederhauser of Rohm & Haas.^[19]

F.A. Cotton Medal for Excellence in Chemical Research

The F.A. Cotton Medal is awarded annually by the American Chemical Society, and sponsored by the The F. Albert Cotton Endowment Fund. Previous winners have included :
2012 R. Graham Cooks, Purdue University;^[20] 2011 George M. Whitesides, Harvard University; 2010 Peter J. Stang, University of Utah; 2009 Richard N. Zare, Stanford University; 2008 Chi-Huey Wong, The Scripps Research Institute, and National Taiwan University; 2007 Jacqueline K. Barton, California Institute of Technology; 2006 Robin M. Hochstrasser, University of Pennsylvania; 2005 Richard H. Holm, Harvard University; 2004 Albert Eschenmoser, Swiss Federal Institute of Technology, Zurich, and Scripps Research Institute; 2003 Gabor A. Somorjai, University of California, Berkeley; 2002 Ada Yonath, Weizman Institute of Science; 2001 Samuel J. Danishefsky, Department of Chemistry, Columbia University; 2000 Tobin J. Marks, Department of Chemistry, Northwestern University; 1999 Alexander Pines, Department of Chemistry, University of California, Berkeley; 1998 JoAnne Stubbe, Department of Chemistry, Massachusetts Institute of Technology; 1997 Pierre-Gilles de Gennes, École Supérieure de Physique et de Chimie Industrielles de la Ville de Paris, Collège de France; 1996 George A. Olah, Department of Chemistry, University of Southern California; 1995 F. Albert Cotton, Department of Chemistry, Texas A&M University ^[21]

Death

Cotton died on February 20, 2007 in College Station, Texas from complications of a head injury he suffered in a fall in October 2006.^[22] He was survived by his wife, the former Diane Dornacher, whom he married in 1959, and their two daughters, Jennifer and Jane.^[3] The Brazos County Sheriff's Department opened an investigation into his death, describing his death as "suspicious

Geoffrey Wilkinson

Sir Geoffrey Wilkinson
Born	14 July 1921 Springside, England
Died	26 September 1996 (aged 75) London, England
Nationality	United Kingdom
Fields	Inorganic chemistry
Institutions	University of California, Berkeley Harvard University Imperial College
Alma mater	Imperial College
Doctoral advisor	Henry Vincent Aird Briscoe
Known for	Homogeneous transition metal catalysis
Notable awards	Nobel Prize in Chemistry (1973) Fellow of the Royal Society[1]

Sir Geoffrey Wilkinson FRS^[1] (14 July 1921 – 26 September 1996) was a Nobel laureate English chemist who pioneered inorganic chemistry and homogeneous transition metal catalysis.^[2]

Contents

• 1 Biography
• 2 Work
• 3 References
• 4 External links

Biography

Wilkinson was born at Springside, Todmorden, in Yorkshire. His father,Henry Wilkinson,^[3] was a master house painter and decorator; his mother,Ruth,^[3] worked in a local cotton mill. One of his uncles, an organist and choirmaster, had married into a family that owned a small chemical company making Epsom and Glauber's salts for the pharmaceutical industry; this is where he first developed an interest in chemistry.
He was educated at the local council primary school and, after winning a County Scholarship in 1932, went to Todmorden Grammar School. His physics teacher there, Luke Sutcliffe, had also taught Sir John Cockcroft, who received a Nobel Prize for "splitting the atom".

Wilkinson's catalyst RhCl(PPh₃)₃

In 1939 he obtained a Royal Scholarship for study at Imperial College London, from where he graduated in 1941. In 1942 Professor Friedrich Paneth was recruiting young chemists for the nuclear energy project. Wilkinson joined and was sent out to Canada, where he stayed in Montreal and later Chalk River Laboratories until he could leave in 1946. For the next four years he worked with Professor Glenn T. Seaborg at University of California, Berkeley, mostly on nuclear taxonomy.^[4] He then became a Research Associate at the Massachusetts Institute of Technology and began to return to his first interest as a student - transition metal complexes of ligands such as carbon monoxide and olefins.
He was then at the Harvard University from September 1951 until he returned to England in December 1955, with a sabbatical break of nine months in Copenhagen. At Harvard, he still did some nuclear work on excitation functions for protons in cobalt, but had already begun to work on olefin complexes.
In June 1955 he was appointed to the chair of Inorganic Chemistry at Imperial College London, and from then on worked almost entirely on the complexes of transition metals.
In 1980 he was awarded an honorary doctorate of science from the University of Bath. Imperial College London named a new hall of residence after him, which opened in October 2009.
He was married, with two daughters.

Work

Structure of ferrocene Fe(C₅H₅)₂

He is well known for his development of Wilkinson's catalyst RhCl(PPh₃)₃, and for the discovery of the structure of ferrocene. Wilkinson's catalyst is used industrially in the hydrogenation of alkenes to alkanes.^[5]
He received many awards, including the Nobel Prize for Chemistry in 1973 for his work on “organometallic compounds” (with Ernst Otto Fischer). He is also well known for writing, with his former doctoral student F. Albert Cotton, "Advanced Inorganic Chemistry", often referred to simply as "Cotton and Wilkinson", one of the standard inorganic chemistry textbooks.[