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William Lipscomb

William Nunn Lipscomb Jr. (December 9, 1919 – April 14, 2011) was an American inorganic and organic chemist renowned for his pioneering work on the structure and bonding of boranes, for which he was awarded the 1976 Nobel Prize in Chemistry.^[1] His research illuminated fundamental problems in chemical bonding and extended to protein crystallography and enzyme mechanisms, influencing fields from inorganic chemistry to biochemistry. Lipscomb's career spanned over six decades, marked by innovative theoretical and experimental approaches that advanced molecular structure determination.^[2] Born in Cleveland, Ohio, Lipscomb moved to Lexington, Kentucky, shortly after his birth and developed a strong connection to his Kentucky roots, where he grew up with two sisters. He earned a bachelor's degree in chemistry from the University of Kentucky in 1941 and pursued graduate studies at the California Institute of Technology, completing his Ph.D. in 1946 under the supervision of Linus Pauling, focusing on the crystal structure of methylammonium chloride.^[2]^[3] Early in his career, he joined the University of Minnesota as an instructor in 1946, rising to full professor by 1954, before moving to Harvard University in 1959, where he held the Abbott and James Lawrence Professorship of Chemistry from 1971 until his retirement in 1990. Lipscomb's most celebrated contributions centered on boranes, complex boron-hydrogen compounds whose unusual electron-deficient bonding challenged conventional valence theory.^[2] Beginning in the early 1950s, he developed the styx formalism and three-center two-electron bond model to describe their structures, culminating in his seminal book Boron Hydrides (1963) and key papers, such as the 1954 work with W. H. Eberhardt and others on diborane. This research not only resolved the bonding paradoxes in boranes but also provided broader insights into multicenter bonding applicable to other systems.^[1] In parallel, from the 1960s onward, he shifted toward biological macromolecules, determining the three-dimensional structure of the enzyme carboxypeptidase A in 1967 and later achieving high-resolution structures of aspartate transcarbamylase, advancing understanding of allosteric regulation in proteins.^[2] He also contributed to theoretical chemistry by developing the extended Hückel molecular orbital method, which his student Roald Hoffmann used in collaboration with Robert B. Woodward to formulate the rules governing pericyclic reactions.^[2] Beyond his scientific achievements, Lipscomb received numerous honors, including election to the National Academy of Sciences in 1961, the Peter Debye Award from the American Chemical Society, and honorary degrees from institutions such as the University of Kentucky (1963) and the University of Munich (1976).^[2] He authored 667 scientific papers and mentored future Nobel laureates, including Hoffmann and Thomas Steitz, leaving a lasting legacy in structural chemistry. In his personal life, Lipscomb enjoyed tennis and playing the clarinet in classical chamber music ensembles, and he remained active in research even after retirement until his death in Cambridge, Massachusetts.^[2]

Early Life and Education

Early Life

William Nunn Lipscomb Jr. was born on December 9, 1919, in Cleveland, Ohio, to William Nunn Lipscomb Sr., a physician, and Edna Patterson (Porter) Lipscomb, a music teacher.^[4]^[5] His family had a legacy of physicians on his father's side, with his grandfather and great-grandfather also in the medical profession, though Lipscomb himself would diverge from this path.^[6] Within a year of his birth, the family relocated to Lexington, Kentucky, where Lipscomb spent his formative years.^[2] He grew up in a household with two sisters, Virginia and Helen, in an environment rich in music and intellectual encouragement, despite lacking a direct scientific family background.^[5] His parents fostered independence and curiosity; his mother provided him with a Gilbert chemistry set at age 12, sparking his early experiments, while his father, leveraging his medical connections, helped procure additional chemicals at a discount.^[7]^[8] Music also played a central role, as Lipscomb took up the clarinet at a young age, participating in family recitals alongside his accomplished pianist and composer sister Helen.^[5]^[6] Lipscomb's childhood hobbies centered on scientific exploration, leading him to build an extensive home laboratory by his early teens. He conducted experiments such as making stink bombs, fireworks, and even attempting to isolate large quantities of urea from urine, once prompting a rare caution from his mother about safety.^[7]^[5] These pursuits reflected his growing fascination with chemistry and physics, often reading advanced texts independently. The family faced hardship in 1937 when Helen contracted polio at age 17, leading to social stigma that forced their father to close his medical practice and retrain as a psychiatrist, yet this did not dampen the supportive atmosphere for Lipscomb's interests.^[5]^[6] He attended high school in Lexington, graduating in 1937, during which time his home lab grew so substantial that its donation to the school upon graduation more than doubled the institution's equipment.^[7] That same year, Lipscomb received the Bausch and Lomb Honorary Science Award for his aptitude in science, recognizing his precocious talent.^[2] These early experiences laid the foundation for his transition to formal studies at the University of Kentucky.^[6]

Education

Lipscomb earned a Bachelor of Science degree in chemistry from the University of Kentucky in 1941, where his studies were supported by a music scholarship that allowed him to pursue his growing interest in science alongside his musical talents.^[9] During his undergraduate years in Lexington, he received foundational training in inorganic and organic chemistry, as well as physics and mathematics, which ignited his passion for molecular structures. His early exposure included qualitative organic analysis, leading to his first publication on the direct preparation of certain organic compounds. In the fall of 1941, Lipscomb entered graduate school at the California Institute of Technology (Caltech), initially planning to study theoretical quantum mechanics in the physics department but switching to chemistry early in 1942 under the influence of Linus Pauling.^[2] He completed his PhD in chemistry in 1946 under Pauling's supervision, with thesis research centered on the molecular structures of inorganic solids using X-ray diffraction and electron diffraction techniques. This work incorporated early computational approaches, such as least-squares refinement methods for crystal structure analysis, in collaboration with Edward Hughes. Lipscomb's graduate studies were significantly interrupted by World War II, during which he contributed to national defense research from 1942 until the end of 1945, including projects on smoke obscuration to conceal shipbuilding in Los Angeles and analysis of nitroglycerin-nitrocellulose rocket propellants at Caltech. Two chapters of his thesis remained classified due to their wartime applications. Pauling's mentorship during this period profoundly shaped Lipscomb's approach, emphasizing original research in quantum chemistry and X-ray crystallography as tools for understanding chemical bonding.^[2] As a child, his fascination with rocks and minerals had foreshadowed this crystallography focus.^[2]

Scientific Research

Nuclear Magnetic Resonance and Chemical Shifts

During his tenure at the University of Minnesota from 1946 to 1959, William Lipscomb pioneered the application of nuclear magnetic resonance (NMR) spectroscopy in the 1950s to investigate the structures of boron compounds, particularly boranes and related hydrides, at a time when the technique was still emerging for such analyses. This early adoption allowed for non-destructive probing of molecular environments in volatile and electron-deficient species that were challenging to study via X-ray diffraction alone. In 1966, Lipscomb advanced the theoretical understanding of NMR chemical shifts through his seminal work, which linked observed resonance frequency variations to electron density distributions and molecular orbital interactions. He demonstrated that paramagnetic and diamagnetic contributions, calculated via quantum mechanical methods, dominate these shifts, enabling more accurate predictions for light elements like boron.^[10] The standard expression for the chemical shift is given by

\delta = \frac{\nu_\text{sample} - \nu_\text{reference}}{\nu_\text{reference}}

in parts per million (ppm), where \nu denotes resonance frequency; Lipscomb's contributions emphasized interpreting \delta through self-consistent field molecular orbital theory to correlate shifts with bonding electron densities. Lipscomb's NMR applications were instrumental in elucidating the structures of boranes, such as distinguishing apical and basal boron environments in \ce{B5H9} via ^{11}B chemical shifts, marking some of the first structural insights into these clusters using the method. He collaborated closely with Gareth R. Eaton on instrumentation enhancements, including improved sensitivity for ^{11}B and ^1H spectra, which facilitated detailed studies compiled in their 1969 monograph NMR Studies of Boron Hydrides and Related Compounds. These efforts not only refined structural assignments but also informed his broader bonding theories by revealing dynamic tautomerism in hydride exchanges.^[10]

Boron Chemistry and Bonding Theory

From the late 1940s through the 1970s, primarily at the University of Minnesota (1946–1959) and later at Harvard University (from 1959), William Lipscomb conducted pioneering X-ray crystallography studies on boron hydrides, or boranes, determining the molecular structures of key compounds such as diborane (B₂H₆) and tetraborane (B₄H₁₀), and analyzing the structure of decaborane (B₁₀H₁₄). These investigations revealed the unexpected geometries of these electron-deficient molecules, challenging traditional two-center two-electron bonding models and highlighting the need for new theoretical frameworks to explain their stability.^[10] His group's work utilized low-temperature crystallographic techniques to capture the volatile boranes in solid form, providing precise atomic positions for both boron and hydrogen atoms that formed the basis for subsequent bonding theories.^[10] A cornerstone of Lipscomb's contributions was the development of the three-center two-electron (3c-2e) bond concept, introduced in 1954 alongside William H. Eberhardt and B. L. Crawford Jr., to account for multicenter bonding in electron-deficient compounds like boranes. This model posits that two electrons are delocalized over three atomic centers, enabling the description of bridging hydrogen bonds in structures such as diborane, where the banana bonds—curved, three-center bonds between two boron atoms and a hydrogen—link the terminal B-H units. In diborane, four such 3c-2e bonds stabilize the molecule, explaining its bridged configuration without violating valence rules. Extending this to larger boranes, Lipscomb's analyses demonstrated polyhedral frameworks, such as the open decaborane structure, where boron atoms form cage-like arrangements stabilized by similar multicenter interactions. His structural determinations provided the empirical foundation for later electron-counting rules, such as Wade's rules (proposed in the early 1970s), which predict cluster geometries based on skeletal electron counts, confirming that borane anions like B₁₀H₁₀²⁻ adopt closo-icosahedral shapes.^[11]^[10] Lipscomb's Nobel Prize in Chemistry in 1976 was awarded specifically "for his studies on the structure of boranes illuminating problems of chemical bonding," recognizing how these insights revolutionized understanding of non-classical bonding in electron-poor systems. In his Nobel lecture, he emphasized the polyhedral topology of boranes and the role of 3c-2e bonds in enabling filled-orbital descriptions, drawing parallels to aromaticity in carbon clusters. Complementing experimental work, Lipscomb pioneered early computational approaches using molecular orbital theory to predict borane geometries; for instance, extended Hückel calculations on B₅H₉ and B₁₂H₁₂²⁻ corroborated X-ray structures and forecasted reaction pathways in boron cluster rearrangements. These methods laid groundwork for quantum chemical modeling of multicenter bonds, influencing later studies in main-group chemistry.^[1]^[10]

Structural Biology of Enzymes

In the late 1960s, William Lipscomb shifted his research focus at Harvard University toward the structural biology of enzymes, leveraging X-ray crystallography to elucidate the three-dimensional architectures of complex proteins and their catalytic mechanisms. His group marked a significant advance in 1967 by determining the structure of carboxypeptidase A (CPA) at 2.8 Å resolution, the first enzyme structure solved in his laboratory. This metalloprotease, involved in protein digestion, features a zinc ion coordinated by histidine residues 69, glutamate 72, and histidine 196 at the active site, which activates a water molecule for nucleophilic attack on peptide bonds during hydrolysis.^[12]^[5] Further investigations of CPA complexes with substrates and inhibitors over subsequent decades revealed dynamic aspects of catalysis, including proton transfer pathways mediated by zinc-bound water and nearby residues like glutamate 270, which polarizes the scissile carbonyl and stabilizes the tetrahedral intermediate. These structural insights highlighted how subtle conformational changes enable substrate specificity and product release, providing a prototype for zinc-dependent proteases and informing early structure-based approaches to inhibitor design for diseases involving dysregulated proteolysis, such as cancer.^[13]^[5] Lipscomb's work extended to aspartate carbamoyltransferase (ATCase) in the 1970s, a key regulatory enzyme in pyrimidine biosynthesis that catalyzes carbamoyl phosphate transfer to aspartate. In collaboration with Thomas A. Steitz, his group obtained initial low-resolution structures around 5.5 Å by 1972, capturing the holoenzyme's oligomeric assembly of catalytic and regulatory subunits. High-resolution refinements in the 1980s, reaching 2.8 Å, delineated the tense (T) and relaxed (R) allosteric states, showing how substrate binding induces large domain rotations—up to 11°—and quaternary shifts exceeding 10 Å between subunits, consistent with the induced-fit model for cooperativity. Effector molecules like cytidine triphosphate (CTP) stabilized the low-activity T state by bridging regulatory chains, while adenosine triphosphate (ATP) promoted the high-activity R state, elucidating feedback inhibition in metabolic flux control.^[5]^[14] Methodologically, Lipscomb pioneered high-resolution X-ray diffraction at low temperatures, around 100–150 K, to mitigate radiation-induced damage in sensitive protein crystals, enabling prolonged data collection from fragile macromolecular samples. This innovation, refined through interdisciplinary efforts with computational modeling, facilitated the atomic-level analysis of enzyme dynamics and ligand interactions. His group's ATCase studies, for instance, used cryogenic techniques to trap transient intermediates, yielding functional models for allosteric transitions that underpin drug targeting of metabolic pathways in pathogens and tumors.^[5] Through these efforts, Lipscomb's laboratory deposited numerous protein structures into the Protein Data Bank, including multiple CPA and ATCase variants that served as benchmarks for validating allosteric theories and guiding inhibitor development against enzymes in nucleotide metabolism. These contributions profoundly shaped structural enzymology, emphasizing how atomic details inform broader biological regulation and therapeutic strategies.^[5]

Additional Contributions

In the 1950s and 1960s, Lipscomb advanced low-temperature X-ray diffraction techniques to analyze unstable compounds that exist as solids only under cryogenic conditions, developing methods that utilized liquid nitrogen and helium cooling for precise single-crystal studies. These innovations allowed for the structural determination of molecules like the nitric oxide dimer (N₂O₂), revealing its asymmetric planar geometry with a twisted conformation, as detailed in early work from his laboratory. Similarly, the technique was applied to hydrazine (N₂H₄), elucidating its orthorhombic crystal structure with hydrogen-bonded chains, which provided insights into its reactivity and bonding. These efforts extended to other volatile substances, demonstrating the versatility of low-temperature crystallography in probing transient chemical species. Lipscomb's contributions to theoretical chemistry included early applications of semi-empirical quantum mechanical methods, such as the extended Hückel theory, to model reaction pathways in electron-deficient systems. His group employed these methods to predict geometries and energies, laying groundwork for computational approaches to reaction mechanisms. These calculations complemented experimental data, offering conceptual frameworks for understanding barrier heights and stereochemistry in organic transformations. Beyond core areas, Lipscomb explored the structures of metal clusters, including iron-sulfur complexes like Roussin's black salt, using X-ray diffraction to reveal their coordination geometries and potential roles in electron transfer. He also investigated semiconductor materials, particularly boron-based compounds, contributing to models of their electronic properties through structural analysis. Throughout his career, Lipscomb authored 667 scientific papers, including influential reviews that extended multicenter bonding theories—initially developed for boranes—to transition metal systems, highlighting delocalized electron distributions in cluster compounds.

Professional Career

Academic Positions

Following his Ph.D. from the California Institute of Technology in 1946, Lipscomb joined the faculty of the University of Minnesota as an assistant professor of physical chemistry.^[2] He was promoted to associate professor in 1950 and to full professor in 1954, remaining at the institution until 1959.^[5] During this period, he established and led a crystallography laboratory, developing techniques for low-temperature X-ray analysis essential for his structural studies.^[2] In 1959, Lipscomb moved to Harvard University as a professor of chemistry.^[15] He served in this role until 1971, when he was appointed the Abbott and James Lawrence Professor of Chemistry, a position he held until his retirement in 1990.^[5] Additionally, he chaired the Harvard Department of Chemistry from 1962 to 1965.^[6] Throughout his tenure, Lipscomb supervised a large group of Ph.D. students and postdoctoral researchers, fostering a collaborative environment that supported advancements in structural chemistry.^[5] After retiring, Lipscomb became professor emeritus at Harvard, continuing his research and mentoring activities until shortly before his death in 2011.^[15] He also held visiting positions, including a Guggenheim Fellowship at the University of Oxford in 1954–1955 during his Minnesota years.^[5]

Awards and Honors

Lipscomb received his first major recognition early in life with the Bausch and Lomb Honorary Science Award in 1937, presented during his high school years for outstanding achievement in science.^[2] In 1973, he was awarded the American Chemical Society's Peter Debye Award in Physical Chemistry, honoring his pioneering contributions to the understanding of molecular structures through X-ray diffraction studies.^[16] Lipscomb's most prestigious honor came in 1976 with the Nobel Prize in Chemistry, which he received as the sole laureate for his studies on the structure of boranes, elucidating the unusual bonding in these compounds. The prize was presented to him by King Carl XVI Gustaf of Sweden during the Nobel ceremony in Stockholm.^[17] Later in his career, Lipscomb was elected to numerous scientific academies, including the National Academy of Sciences in 1961 and foreign membership in the Royal Netherlands Academy of Sciences and Letters.^[2] In recognition of his structural work on phosphate minerals, the synthetic compound lipscombite, later found in nature, was named after him in the mid-20th century, with natural occurrences identified in the 1970s.^[18] Lipscomb also received multiple honorary doctorates, including a Doctor of Science from the University of Kentucky in 1963 and from the University of Munich in 1976.^[2]

Personal Life and Legacy

Personal Life

Lipscomb married Mary Adele Sargent in 1944.^[19] The couple had three children, though one son died shortly after birth in 1945; the surviving children were son James and daughter Dorothy.^[20]^[21] Mary Adele Lipscomb passed away in 1983.^[5] That same year, Lipscomb married Jean Evans, with whom he had daughter Jenna.^[22] Despite the demands of his scientific career, Lipscomb maintained close ties with his family throughout his life.^[5] Lipscomb pursued several personal interests outside his professional work, including playing the clarinet—a lifelong hobby supported by a music scholarship during his undergraduate years—and tennis, which he enjoyed into later life.^[5]^[20] He was also known for his playful sense of humor, often engaging in lighthearted pranks with colleagues and family.^[5] In his later years, Lipscomb dealt with health challenges stemming from a 1943 laboratory accident that caused lasting lung damage, making him sensitive to smoke and pollutants.^[20] He died on April 14, 2011, in Cambridge, Massachusetts, at age 91 from pneumonia and complications following a fall.^[15]^[9] A memorial service was held for him on September 10, 2011, at Harvard University's Memorial Church.^[23]

Legacy and Influence

William Lipscomb's mentorship profoundly shaped the careers of several prominent chemists, including three future Nobel laureates in Chemistry. Roald Hoffmann, who earned the 1981 Nobel Prize for his work on the conservation of orbital symmetry in chemical reactions, completed his PhD under Lipscomb's supervision at Harvard University, where he developed early quantum chemistry theories for polyhedral molecules. Thomas A. Steitz, co-recipient of the 2009 Nobel Prize for studies on the structure and function of the ribosome, pursued his doctoral research in Lipscomb's laboratory, focusing on the X-ray crystallography of carboxypeptidase A, which honed his expertise in structural biology. Ada Yonath, who shared the 2009 Nobel Prize for ribosome research, spent time in Lipscomb's Harvard lab during her postdoctoral stint at MIT, gaining insights into protein crystallography that informed her later groundbreaking work.^[24]^[25]^[26] Lipscomb's foundational contributions to boron chemistry established key principles for understanding electron-deficient bonding in cluster compounds, influencing subsequent developments in materials science. His structural analyses of boranes and carboranes provided the theoretical framework for designing boron-rich materials with unique properties, such as high thermal stability and neutron absorption, which have found applications in advanced composites and radiation shielding. In medicine, carboranes—icosahedral boron-carbon clusters elucidated by Lipscomb's group—serve as platforms for targeted drug delivery and boron neutron capture therapy for cancer, enabling precise tumor irradiation while sparing healthy tissue. Similarly, his pioneering enzyme crystallography advanced structural biology, facilitating the design of protease inhibitors.^[27]^[28]^[29] Through his extensive publications, Lipscomb disseminated his interdisciplinary approaches, authoring several influential books that synthesized advances in boron chemistry and spectroscopy, including Boron Hydrides (1963) and NMR Studies of Boron Hydrides and Related Compounds (1969, co-authored with Gareth R. Eaton). His laboratory contributed numerous high-resolution structures to the Protein Data Bank, such as those of carboxypeptidase A and other enzymes, which remain foundational references for biochemical modeling. Additionally, Lipscomb provided autobiographical sketches in Nobel Prize volumes, reflecting on his shift from borane structures to biological macromolecules and the integration of computational methods. His early use of quantum mechanical calculations for molecular orbitals played a pivotal role in the rise of computational chemistry, bridging theoretical predictions with experimental validation.^[2] Following his death in 2011, Lipscomb's interdisciplinary legacy was celebrated in prominent obituaries, including one in Nature that highlighted his versatile contributions from music-inspired creativity to pioneering cluster bonding theories.^[30]

References

[1]
William Lipscomb – Facts - NobelPrize.org
William N. Lipscomb Nobel Prize in Chemistry 1976. Born: 9 December 1919, Cleveland, OH, USA. Died: 14 April 2011, Cambridge, MA, USA.
[2]
William Lipscomb – Biographical - NobelPrize.org
William Lipscomb died on April 14, 2011. This autobiography/biography was written at the time of the award and later published in the book series Les Prix ...
[3]
Obituary for Dr. William Nunn Lipscomb, Jr
Apr 14, 2011 · William Nunn Lipscomb Jr. was born in Cleveland on Dec. 9, 1919. His father was a physician. His mother, Edna Patterson (Porter) Lipscomb ...
[4]
[PDF] William N. Lipscomb - Biographical Memoirs
From 1993 to 2010, Lipscomb participated in nearly all the Ig Nobel Prize ceremonies, as detailed in a special issue of the Annals of Improbable Research ( ...
[5]
William Nunn Lipscomb Jr. - Harvard Gazette
Jun 4, 2013 · His family moved to Lexington, Kentucky, and he grew up in an environment of music and science. Lipscomb excelled as a clarinetist but was also ...Missing: birth childhood hobbies
[6]
Lipscomb Obituary - ACA History
He was born on December 9, 1919 in Cleveland, OH. A year later, his music teacher mother and physician father moved the family to Lexington, KY where he spent ...Missing: early hobbies
[7]
Early-Years Family Stories - William Lipscomb Scientific Character
When Bill Lipscomb was young, he set up a chemistry lab at home. This dates from age eleven when my mother gave me one of those Gilbert Chemistry Sets that ...Missing: hobbies | Show results with:hobbies
[8]
UK Loses Alumnus, Nobel Laureate - UKNow - University of Kentucky
Apr 18, 2011 · Lipscomb, who came from a musical family, pursued his love of music at UK as well and attended UK on a music scholarship. “There's a lot of ...
[9]
[PDF] William N. Lipscomb - Nobel Lecture
While we understand some of the contributions to chemical shift, diamagnetic and large temperature-independent paramagnetic effects, the use of this method for ...
[10]
The Valence Structure of the Boron Hydrides - AIP Publishing
Lipscomb; The Valence Structure of the Boron Hydrides. J. Chem. Phys. 1 June 1954; 22 (6): 989–1001. https://doi.org/10.1063/1.1740320. Download citation ...<|control11|><|separator|>
[11]
THE STRUCTURE OF CARBOXYPEPTIDASE A, IX. THE X ... - PNAS
-The peptide chain, showing (near the center) Zn with its three ligainds from the protein, the disulfide bond (at the right), the N-terminus (at the bottom), ...
[12]
Carboxypeptidase A mechanisms. - PNAS
In this paper, the relationship between structural studies and more recent biochemical studies is discussed, with emphasis on the ambiguities in the mechanisms ...
[13]
Structure of a single amino acid mutant of aspartate ...
Eric Gouaux, William N. Lipscomb. Crystal structure of CTP‐ligated T state aspartate transcarbamoylase at 2.5 Å resolution: Implications for ATCase mutants ...
[14]
William Lipscomb dies at 91 - Harvard Gazette
Apr 15, 2011 · Lipscomb was professor of chemistry at Harvard ... Before arriving at Harvard, he taught at the University of Minnesota from 1946 to 1959.Missing: positions | Show results with:positions<|control11|><|separator|>
[15]
Peter Debye Award in Physical Chemistry Recipients
1973 - William N. Lipscomb, Jr. 1972 - Clyde A. Hutchison, Jr. 1971 - Norman Davidson; 1970 - Oscar K. Rice; 1969 - Paul ...
[16]
Award ceremony speech - NobelPrize.org
William Lipscomb has achieved this. Through his theories and his experimental studies he has completely governed the vigorous growth which has characterized ...Missing: Carl | Show results with:Carl
[17]
[PDF] Lipscombite (Fe2+,Mn2+)Fe (PO4)2(OH)2 - Handbook of Mineralogy
Mineral Group: Dimorphous with barbosalite. Occurrence: In a hydrothermally altered phosphate zone of a complex granite pegmatite. (Sapucaia mine, Brazil).
[18]
William Lipscomb Biography, Life, Interesting Facts - SunSigns.Org
Apr 14, 2011 · As a child and teenager, William Lipscomb was fascinated by science. Like many children, he had a chemistry set. He also loved to spend time out ...Missing: early hobbies
[19]
Eulogy - WLipscomb
Apr 14, 2011 · Bill's father was a physician, as was Bill's grandfather and great grandfather. Bill's father, William Lipscomb Sr., died three years before ...
[20]
William N. Lipscomb Jr., Nobel Prize-Winning Chemist, Dies at 91
Apr 15, 2011 · When he was a year old, his family moved to Lexington, Ky. ... Lipscomb told his son, James, that he received a C in high school chemistry.<|control11|><|separator|>
[21]
William N. Lipscomb dies at 91; won Nobel Prize in chemistry
Apr 16, 2011 · His father was a prosperous physician who lost his career and livelihood when young William's sister Helen contracted polio at age 17. No ...
[22]
Bill Lipscomb is gone. - Improbable Research
Apr 15, 2011 · UPDATE: A memorial event for Professor Lipscomb is scheduled to happen Saturday, September 10, at Harvard's Memorial Church, from 2:00-3:00 ...
[23]
Roald Hoffmann – Biographical - NobelPrize.org
In 1962 I received my doctorate, as the first Harvard Ph.D. of both Lipscomb and Gouterman. Several academic jobs were available, and I was also offered a ...Missing: William | Show results with:William
[24]
Thomas A. Steitz – Biographical - NobelPrize.org
Some of the important mentors in my early career development: (A) Bob Rosenberg, my chemistry professor at Lawrence College, (B) William Lipscomb, my Ph.D.
[25]
Nobel Laureate William Lipscomb Dies At 91 - C&EN
Apr 19, 2011 · He earned a bachelor of science in chemistry at the University of Kentucky in 1941 and then entered graduate school at the California Institute ...Missing: biography | Show results with:biography<|control11|><|separator|>
[26]
Thomas Jefferson, Alice in Wonderland, Polyhedral Boranes, and ...
The impact of the studies of William N. Lipscomb and his collaborators on the development of polyhedral borane chemistry, and more broadly on the general ...
[27]
New keys for old locks: carborane-containing drugs as platforms for ...
Jun 19, 2019 · Icosahedral carboranes in medicine are still an emerging class of compounds with potential beneficial applications in drug design.Missing: legacy | Show results with:legacy<|control11|><|separator|>
[28]
Thomas Arthur Steitz. 23 August 1940—9 October 2018
Dec 1, 2021 · Lipscomb was obviously pleased because he offered to go to Minneapolis and play at their wedding. Tom and Joan became one of molecular biology's ...
[29]
William Nunn Lipscomb Jr (1919–2011) - Nature
May 18, 2011 · Lipscomb, who died on 14 April, was born in Cleveland, Ohio, to a physician father and housewife mother. The family moved to Lexington when ...<|control11|><|separator|>
[30]
Quantum Optics Applications of Hexagonal Boron Nitride Defects
Feb 13, 2025 · This review provides an overview of the fundamental concepts and key applications of hBN, including quantum sensing, quantum key distribution, ...