Hubbry Logo
Geoffrey WilkinsonGeoffrey WilkinsonMain
Open search
Geoffrey Wilkinson
Community hub
Geoffrey Wilkinson
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Geoffrey Wilkinson
Geoffrey Wilkinson
Geoffrey Wilkinson
View on Wikipedia
from Wikipedia

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.[6][7]

Key Information

Education and early life

[edit]

Wilkinson was born at Springside, Todmorden, in the West Riding of Yorkshire. His father, Henry Wilkinson, was a master house painter and decorator; his mother, Ruth, 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". In 1939 he obtained a Royal Scholarship for study at Imperial College London, from where he graduated in 1941, with his PhD awarded in 1946 entitled "Some physico-chemical observations of hydrolysis in the homogeneous vapour phase".[8][2][9]

Wilkinson's catalyst RhCl(PPh3)3

Career and research

[edit]

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.[10] 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 at 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.

Structure of ferrocene Fe(C5H5)2

Wilkinson is well known for his popularisation of the use of Wilkinson's catalyst RhCl(PPh3)3 in catalytic hydrogenation, and for the discovery of the structure of ferrocene. Wilkinson's catalyst is used industrially in the hydrogenation of alkenes to alkanes.[11][12]

He supervised PhD students and postdoctoral researchers including F. Albert Cotton, Richard A. Andersen, John A. Osborn, Alan Davison[3][4] and Malcolm Green.[5]

Awards and honours

[edit]

Wilkinson received many awards, including the Nobel Prize for Chemistry in 1973[2] 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.[13]

He was elected a Fellow of the Royal Society (FRS) in 1965.[1] 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. Wilkinson Hall is named in his honour.[14]

Personal life

[edit]

Wilkinson was married to Lise Schou, a Danish plant physiologist whom he had met at Berkeley. They had two daughters, Anne and Pernille.[1]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Geoffrey Wilkinson

View on Grokipedia
from Grokipedia
Sir Geoffrey Wilkinson (14 July 1921 – 26 September 1996) was an English inorganic chemist renowned for his pioneering contributions to , particularly the elucidation of sandwich compounds such as and the development of for homogeneous hydrogenation reactions. Born in the small village of Springside near in , , to a family with ties to the local chemical industry, Wilkinson demonstrated early academic promise by winning scholarships to attend Todmorden Secondary School and later , where he graduated at the top of his class in chemistry in 1941. During , Wilkinson contributed to the British atomic energy project, working from 1943 to 1946 at the in on uranium isotope separation and . After the war, he pursued postdoctoral research at the (1946–1950), focusing on , before moving to the Massachusetts Institute of Technology as a research associate in 1950 and then to as an from 1951 to 1955. In 1956, he returned to as professor of , a position he held until his retirement in 1988, though he continued active research thereafter. At Imperial, Wilkinson established a world-leading group in transition metal chemistry, mentoring numerous students and collaborators while authoring the influential textbook Advanced Inorganic Chemistry (first edition 1962) with , which became a standard reference in the field. Wilkinson's most notable achievements centered on the chemistry of complexes, beginning with his independent proposal in 1952—alongside Robert Woodward—of the π-bonded sandwich structure for , a breakthrough that opened the field of and earned him the in 1973, shared with Ernst Otto Fischer for their work on such compounds. He further advanced synthetic applications through the invention of , tris()rhodium(I) chloride, in 1965, which revolutionized selective in and remains widely used in industry. His research extended to complexes of platinum-group metals like , , and , as well as contributions to processes such as . Elected a in 1965 and knighted in 1976, Wilkinson was celebrated for his rigorous, hands-on approach to experimental chemistry and his role in shaping modern inorganic and organometallic paradigms. In his personal life, he married Lise Sølver, a Danish physiologist, in 1952; they had two daughters and shared interests in music and travel until his sudden death from a heart attack in .

Early Life and Education

Childhood and Family

Geoffrey Wilkinson was born on 14 July 1921 in Springside, a small village near in the , . His family was working-class, with his father, Henry Wilkinson, working as a master , a passed down from his grandfather. Wilkinson's mother, Ruth, came from a background of hill farmers but worked in the local cotton mills from an early age, reflecting the industrial labor common in the region during the . As the eldest of three children in a modest , Wilkinson grew up amid economic challenges typical of Yorkshire's textile-dependent communities, where the home was later deemed unfit for habitation and demolished. Despite these constraints, his parents emphasized education, fostering an environment that valued learning. An uncle, a local and choirmaster, further shaped dynamics by marrying into a that owned a small chemical factory producing and Glauber's salts, providing Wilkinson with early access to basic equipment. Wilkinson's formative interests in science emerged from the surrounding industrial landscape of mills and his hands-on exposure to chemistry through visits to the family-connected chemical works, where he played in a rudimentary and observed simple processes. This self-directed was supplemented by reading and basic experiments, sparking his passion for the subject before formal at Todmorden Secondary School, which he entered on a county in 1932.

Academic Training

Geoffrey Wilkinson attended the local council primary school in Todmorden before winning a County Scholarship in 1932, which enabled him to enroll at Todmorden Secondary School. There, he demonstrated exceptional aptitude in the sciences during , laying a strong foundation for his future academic pursuits. In 1939, Wilkinson secured a prestigious Royal Scholarship to study chemistry at Imperial College of Science and Technology in . Despite the disruptions of , he completed his BSc degree with First Class Honours in 1941, excelling under challenging wartime conditions that affected university operations across Britain. Following his undergraduate studies, Wilkinson began doctoral research at Imperial College under the supervision of Professor H. V. A. Briscoe, initially focusing on topics amid the ongoing war. In late , he was recruited by Professor F. A. Paneth for the British nuclear energy project and directed to the National Research Council of Canada, where he worked from 1943 to 1946 on uranium isotope separation at facilities in and —contributing to atomic energy research essential for the war effort. Wilkinson completed his PhD in 1946 at Imperial College, with a thesis titled Some Physico-Chemical Observations on in the Homogeneous Vapour Phase, awarded based on his pre-war and wartime investigations into mechanisms. This period marked the culmination of his formal academic training, blending rigorous scientific inquiry with practical applications under duress.

Professional Career

Early Research Roles

Following his PhD, Wilkinson arrived at the in August 1946 as a in the Department of Chemistry, where he collaborated closely with . Over the next four years until 1950, his primary focus was nuclear taxonomy at the Radiation Laboratory, where he utilized cyclotrons to synthesize and characterize numerous new neutron-deficient isotopes, contributing significantly to postwar nuclear research in the aftermath of the . He also conducted studies on the optical spectra of uranium compounds during this period. In the fall of 1950, Wilkinson relocated to the Massachusetts Institute of Technology (MIT) as a under Charles D. Coryell from 1950 to 1951. This brief but pivotal role marked his transition from to transition metal chemistry, where he began investigating the structures and properties of metal carbonyls and olefin complexes, laying foundational groundwork for his later organometallic pursuits. Wilkinson then joined in September 1951 as an assistant professor of chemistry, remaining until December 1955. During his time at Harvard, he took a nine-month in 1954–1955 at the as a John Simon Guggenheim Fellow. At Harvard, his research continued some nuclear studies while initiating investigations into the structures and properties of olefin complexes and coordination chemistry. He collaborated with colleagues on elucidating the properties of metal carbonyls, contributing to broader understanding of coordination chemistry.

Tenure at Imperial College

In 1955, Geoffrey Wilkinson was appointed to the Chair of Inorganic Chemistry at , succeeding H. V. A. Briscoe in what was then the only such chair in Britain; he took up the position in January 1956 and held it until his formal retirement in 1988. This appointment marked the beginning of his long-term commitment to the institution, where he focused on building a robust program in amid the post-war expansion of British higher education. During his tenure, Wilkinson assumed key leadership roles that shaped the department's direction. In 1976, he became head of the Chemistry Department, a position he held into the , overseeing administrative and academic growth while maintaining a hands-on approach to research priorities. He established a major research group in organometallics, attracting collaborators and resources that transformed Imperial into a global hub for chemistry studies. His leadership emphasized rapid innovation and interdisciplinary collaboration, often likened to an intense, productive "" in the lab. Wilkinson was renowned for his mentorship, supervising numerous PhD students and postdoctoral fellows in a supportive yet demanding environment that encouraged independence and creativity. Notable among his students were Malcolm L. H. Green and William P. Griffith, who went on to distinguished careers in , as well as Fred Jardine, whose work contributed to key developments in complexes. He fostered a collaborative lab culture, providing direct guidance on experimental techniques while tolerating diverse personalities and unconventional approaches, which helped nurture a generation of organometallic chemists. Administratively, Wilkinson contributed to the department's by advocating for enhanced funding and resources, engaging directly with and officials to support the growth of chemistry facilities at Imperial during a period of scientific advancement in the . His efforts helped position the institution as a leader in experimental inorganic research, even as he continued active involvement in the lab until shortly before his death in 1996.

Scientific Contributions

Ferrocene and Sandwich Compounds

In 1951–1952, while serving as an assistant professor at , Geoffrey Wilkinson independently synthesized dicyclopentadienyliron, now known as , marking a pivotal moment in the development of . Prompted by a recent report of the compound's preparation, Wilkinson employed a method involving the reaction of iron salts with under anaerobic conditions. Specifically, ferric was reduced to ferrous using iron powder in , followed by treatment with —prepared from and sodium in a mixture of and —to yield the air-stable, orange crystalline in yields of 67–73%. This synthesis highlighted the compound's unexpected stability and aromatic-like properties, contrasting with typical organoiron derivatives. Preliminary crystallographic analysis by Wilkinson's group, conducted in collaboration with J. Waser, revealed a groundbreaking "sandwich" structure: the iron atom positioned centrally between two parallel cyclopentadienyl (Cp) rings, with the ring planes approximately 3.3 apart and the iron ~1.66 from each ring . This arrangement was detailed in a 1952 publication, which proposed the η⁵-bonding mode, wherein all five carbon atoms of each Cp coordinate symmetrically to the iron center, facilitating delocalized . The molecular is represented as (η5\ceC5H5)2\ceFe(\eta^5-\ce{C5H5})_2\ce{Fe}, with the stability arising from filled molecular orbitals involving donation from the Cp π-system to the metal and back-donation from iron d-orbitals, achieving an 18-electron configuration. Wilkinson's findings paralleled contemporaneous independent work by Ernst Otto Fischer in , who also synthesized and confirmed the sandwich motif through analogous structural studies, with both groups publishing in and establishing the η⁵ coordination as a hallmark of these complexes. Extending this framework in the 1950s, Wilkinson and coworkers prepared related sandwich compounds, including ((η5\ceC5H5)2\ceCo(\eta^5-\ce{C5H5})_2\ce{Co}) and ((η5\ceC5H5)2\ceNi(\eta^5-\ce{C5H5})_2\ce{Ni}), via metathesis reactions of the metal halides with . These analogs demonstrated the versatility of π-bonding between transition metals and cyclic polyenes, inspiring theoretical models that emphasized synergic electron delocalization and influencing subsequent advancements in understanding metal-ligand orbital overlap.

Wilkinson's Catalyst and Homogeneous Catalysis

In 1965, Geoffrey Wilkinson and his collaborators at Imperial College London developed chlorotris(triphenylphosphine)rhodium(I), denoted as RhCl(PPh₃)₃, as the first effective homogeneous catalyst for the hydrogenation of alkenes and alkynes under ambient conditions of 1 atm H₂ pressure and room temperature. This breakthrough was detailed in subsequent work, where the complex was prepared by reducing rhodium(III) chloride with excess triphenylphosphine in refluxing ethanol under a hydrogen atmosphere, yielding a red, air-stable solid that dissolved in organic solvents to form active catalytic species. The catalyst's mild reactivity distinguished it from heterogeneous systems, enabling precise control over reaction selectivity without the need for high pressures or temperatures typically required for industrial hydrogenations. The catalytic mechanism follows a well-defined cycle adhering to the for stable intermediates, beginning with the dissociation of one from the 16-electron precatalyst to generate the active 14-electron species [RhCl(PPh₃)₂]. This is followed by of H₂ to form a dihydride intermediate, coordination of the substrate, migratory insertion of the into one Rh–H bond to produce an alkyl , and finally of the product, regenerating the active catalyst. All intermediates maintain 18-electron configurations, ensuring stability, and the cycle can be simplified as: RhCl(PPh3)3+H2+RCH=CHR’RhCl(PPh3)3+RCH2CH2R’\text{RhCl(PPh}_3)_3 + \text{H}_2 + \text{RCH=CHR'} \rightarrow \text{RhCl(PPh}_3)_3 + \text{RCH}_2\text{CH}_2\text{R'} This associative pathway, confirmed through kinetic studies showing first-order dependence on hydrogen and alkene concentrations, highlights the catalyst's efficiency for terminal and monosubstituted alkenes. Wilkinson's catalyst excels in selective hydrogenation, reducing alkenes in the presence of other functional groups such as nitro, carbonyl, or halide moieties, which remain unaffected under these mild conditions. This selectivity has profoundly influenced industrial processes, particularly in pharmaceutical synthesis, where it enables the targeted reduction of specific double bonds in complex molecules; for instance, its application in the selective hydrogenation of avermectin B1 to produce ivermectin, a broad-spectrum antiparasitic drug, achieved high yields while preserving sensitive structural features. Such precision has facilitated scalable production of therapeutics, underscoring the catalyst's role in advancing homogeneous catalysis for fine chemicals. Variations of the catalyst have extended its utility, including air-stable analogs with modified ligands or counterions that enhance stability or for broader compatibility. Extensions to other substrates, such as the of imines to amines at and 1 atm H₂, demonstrate its versatility, often using the parent complex or slight modifications to achieve high conversions without over-reduction.

Broader Impact on Organometallic Chemistry

Geoffrey Wilkinson's co-authorship of the textbook Advanced Inorganic Chemistry with , first published in 1962 and revised through multiple editions up to the sixth in 1999, established a foundational resource for coordination and . The book systematically integrated theoretical principles with experimental findings, covering metal-ligand interactions, bonding models, and synthetic methods, and became a standard reference that educated generations of chemists on the evolving field. In the 1960s, Wilkinson made key contributions to theoretical frameworks in , including the formulation and validation of the for complexes and models of π-back-bonding in systems involving , olefins, and arenes. These advancements, built on , provided conceptual tools to predict complex stability and reactivity, shifting the discipline from descriptive empiricism toward a more predictive, quantum-informed understanding. His work on back-bonding, for instance, elucidated how electron donation from metal d-orbitals to ligand π* orbitals strengthens bonds in carbonyl and complexes, influencing subsequent theoretical developments. Wilkinson's research group at generated over 550 publications, with a substantial portion focused on metal hydrides, alkyls, carbonyls, and related species, pioneering the use of tertiary ligands to stabilize and tune the reactivity of centers. These efforts, exemplified by foundational discoveries like and , extended organometallic principles to practical domains. Overall, his influence catalyzed a in the field, from ad hoc syntheses to theoretically guided design, enabling breakthroughs in asymmetric for pharmaceutical synthesis and organometallic applications in , such as polymer catalysts and .

Recognition and Awards

Nobel Prize in Chemistry

Geoffrey Wilkinson shared the 1973 with Ernst Otto Fischer for their pioneering work, performed independently, on the chemistry of the organometallic, so-called sandwich compounds. The award was announced by the Royal Swedish Academy of Sciences on 23 October 1973, recognizing Wilkinson's contributions to elucidating the structure and bonding in these novel compounds, particularly , which he had characterized in the early 1950s at . This marked the first Nobel recognition for , highlighting the independent discoveries by Wilkinson and Fischer that demonstrated stable bonding between transition metals and organic ligands in a planar, sandwich-like arrangement. Wilkinson delivered his Nobel lecture titled "The Long Search for Stable Transition Metal Alkyls" on 11 December 1973 in , . In the address, he traced the evolution of his research from the initial structural determination of —which resolved earlier controversies over its and established it as a prototype for metallocene chemistry—to broader advancements in synthesizing stable transition metal-carbon bonds. The lecture emphasized the theoretical and synthetic challenges overcome in developing these compounds, underscoring their role in expanding the scope of organometallic synthesis beyond traditional expectations. The prize validated organometallic chemistry as a mainstream subdiscipline, bridging inorganic and organic chemistry and paving the way for applications in catalysis and materials science; Wilkinson's later work on homogeneous catalysts, such as Wilkinson's catalyst, built upon these foundational insights. The total prize amount was 510,000 Swedish kronor (SEK), shared equally between the laureates. Wilkinson's selection stemmed from multiple nominations emphasizing his insights into the electronic structure and reactivity of sandwich compounds, with no previous Nobel awarded in this area prior to 1973.

Other Major Honors

In addition to the Nobel Prize, Geoffrey Wilkinson received numerous accolades that underscored his enduring influence on inorganic and organometallic chemistry. He received the ACS Award in Inorganic Chemistry in 1966. His election as a (FRS) in 1965 recognized his foundational contributions to , marking him as one of Britain's leading scientists early in his career. He was knighted in the 1976 for services to . Wilkinson's post-Nobel honors further highlighted his innovative work in organometallic compounds. In 1981, the Royal Society awarded him the Royal Medal for his distinguished contributions to preparative , particularly advancements in synthesizing and understanding complexes. That same year, the Royal Society of Chemistry presented him with the Ludwig Mond Award for outstanding research in , celebrating his pioneering studies on metal-carbon bonds and catalytic systems. Later in his career, Wilkinson continued to be honored for his lifetime body of work. In 1996, just weeks before his death, the Royal Society bestowed upon him the in recognition of his exceptional contributions to organotransition metal chemistry and its applications. These awards collectively affirmed his status as a transformative figure in the field, with impacts extending from academic research to industrial catalysis.

Personal Life and Legacy

Family and Personal Details

Geoffrey Wilkinson married Lise Sølver Schou, a Danish plant physiologist, in 1951 after meeting her at the University of California, Berkeley, where both were working in scientific roles. Their partnership provided mutual support in a dual-career academic household, with Lise contributing to plant physiology research while Wilkinson advanced in inorganic chemistry. The couple had two daughters: Anne, born in 1953, and Pernille, born in 1955. Both daughters grew up during Wilkinson's early career moves, including time in , before the family settled with Imperial College London serving as their professional and familial base. Wilkinson enjoyed outdoor pursuits, particularly hiking and walking on the moors and fells around , reflecting his roots in the region. He and his wife also shared an interest in , and later in life, he cultivated a personal connection to by planting 2,000 trees on their country estate. Despite his professional acclaim, Wilkinson maintained a modest lifestyle, residing primarily in the London area while prioritizing family time alongside his demanding work.

Death and Posthumous Influence

Geoffrey Wilkinson died on 26 September 1996 at his home in , at the age of 75, from a heart attack. His passing was marked by a private funeral service, followed by tributes in prominent scientific publications. Obituaries in and praised his distinctive mentorship style, noting his close collaborations with students and colleagues that fostered a global network of researchers in . Wilkinson's legacy endures through institutional honors and the ongoing application of his discoveries. The Royal Society of Chemistry established the Sir Geoffrey Wilkinson Prize in the early 2000s, awarded annually to mid-career scientists for outstanding contributions to , recognizing his transformative influence on the field. His , [RhCl(PPh₃)₃], remains a cornerstone in , enabling efficient and selective reactions that minimize waste and energy use in pharmaceutical and synthesis. Wilkinson's work inspired generations of chemists, establishing as a foundational discipline. His co-authored textbook Advanced Inorganic Chemistry, with its sixth edition published in 1999, continues to serve as a core reference for understanding coordination and organometallic compounds. The centrality of organometallics in modern chemical research is evident in Nobel trends, such as the 2010 Chemistry Prize for palladium-catalyzed cross-coupling reactions, which built directly on Wilkinson's pioneering paradigms.

References

  1. https://pubs.acs.org/doi/10.1021/ic961299i
  2. https://www.nobelprize.org/prizes/chemistry/1973/wilkinson/biographical/
  3. https://www.imperial.ac.uk/about/history/past-people/
  4. https://www.nobelprize.org/prizes/chemistry/1973/summary/
  5. https://www.ypsyork.org/resources/yorkshire-scientists-and-innovators/geoffrey-wilkinson/
  6. https://www.nesacs.org/pub_articles/Wilkinson_tribute.pdf
  7. https://www.ias.ac.in/article/fulltext/reso/030/10/1319-1328
  8. https://www.encyclopedia.com/science/dictionaries-thesauruses-pictures-and-press-releases/wilkinson-geoffrey
  9. https://blogs.imperial.ac.uk/videoarchive/promotion-3-the-chemistry-department/
  10. http://www.orgsyn.org/demo.aspx?prep=CV4P0473
  11. https://pubs.acs.org/doi/10.1021/ja01128a527
  12. https://pubs.rsc.org/en/content/articlelanding/1965/c1/c19650000131
  13. https://pubs.rsc.org/en/content/articlelanding/1966/j1/j19660001711
  14. https://www.sciencedirect.com/science/article/pii/S0277538700845696
  15. https://www.nobelprize.org/prizes/chemistry/1973/press-release/
  16. https://www.nobelprize.org/prizes/chemistry/1973/wilkinson/lecture/
  17. https://www.nobelprize.org/uploads/2018/06/wilkinson-lecture.pdf
  18. https://www.nobelprize.org/uploads/2019/04/prize-amounts-2020.pdf
  19. https://www.nobelprize.org/nomination/archive/list.php?prize=2&year=1973
  20. https://www.acs.org/funding/awards/acs-award-in-inorganic-chemistry/past-recipients.html
  21. https://wilkinsonfoundation.org.uk/home/brief-personal-biography/
  22. https://www.britannica.com/biography/Geoffrey-Wilkinson
  23. https://www.nature.com/articles/384220a0
  24. https://pubs.rsc.org/en/content/articlelanding/2009/gc/b915563p
  25. https://www.acs.org/molecule-of-the-week/archive/w/wilkinsons-catalyst.html
Add your contribution
Related Hubs
User Avatar
No comments yet.