Linus Pauling

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Linus Pauling
Born	Linus Carl Pauling (1901-02-28)February 28, 1901 Portland, Oregon, USA
Died	August 19, 1994(1994-08-19) (aged 93) Big Sur, California, USA
Residence	United States
Nationality	American
Fields	Quantum chemistry Biochemistry
Institutions	As faculty member Caltech (1927–1963) UC San Diego (1967–1969) Stanford (1969–1975) As fellow Center for the Study of Democratic Institutions (1963–1967)
Alma mater	Oregon State University California Institute of Technology (Caltech)
Thesis	The Determination with X-Rays of the Structures of Crystals (1925[1])
Doctoral advisor	Roscoe Dickinson Richard Tolman[2]
Other academic advisors	Arnold Sommerfeld[3] Niels Bohr[3]
Doctoral students	Martin Karplus Jerry Donohue Matthew Meselson Edgar Bright Wilson William Lipscomb[2]
Known for	[show] Alpha sheet Beta sheet Bond order Coiled coil CPK coloring Crystal structure prediction Electronegativity Elucidating chemical bonds and molecular structures Ice-type model Linear combination of atomic orbitals Molecular clock Molecular medicine Orbital overlap Pauling's rules Pauling–Corey–Branson alpha helix Quantum chemistry Quantum graph Resonance (chemistry) Space-filling model Valence bond theory Vitamin C megadosage Xenic acid Advocating nuclear disarmament
Notable awards	Irving Langmuir Award (1931) Davy Medal (1947) Nobel Prize in Chemistry (1954) Nobel Peace Prize (1962) Roebling Medal (1967) Lenin Peace Prize (1968–69) National Medal of Science (1974) Lomonosov Gold Medal (1977) Priestley Medal (1984) Vannevar Bush Award (1989)
Signature
Notes The only person to win two unshared Nobel Prizes.

Linus Carl Pauling (February 28, 1901 – August 19, 1994)^[4] was an American chemist, biochemist, peace activist, author, and educator. He was one of the most influential chemists in history and ranks among the most important scientists of the 20th century.^[5][6] Pauling was one of the founders of the fields of quantum chemistry and molecular biology.^[7]

For his scientific work, Pauling was awarded the Nobel Prize in Chemistry in 1954. In 1962, for his peace activism, he was awarded the Nobel Peace Prize. This makes him the only person to be awarded two unshared Nobel Prizes. He is one of only four individuals to have won more than one Nobel Prize (the others being Marie Curie, John Bardeen, and Frederick Sanger). Pauling is also one of only two people to be awarded Nobel Prizes in different fields, the other being Marie Curie.^[8]

He promoted orthomolecular medicine, megavitamin therapy, dietary supplements, and taking large doses of vitamin C.

Early life and education

Photo of Herman Henry William Pauling, Linus Pauling's father, taken c. 1900.

Pauling was born in Portland, Oregon,^[9][10] as the first-born child of Herman Henry William Pauling (1876–1910) and Lucy Isabelle "Belle" Darling (1881–1926).^[11] He was named "Linus Carl," in honor of Lucy's father, Linus, and Herman's father, Carl.^[12] Lucy's great grandfather William Darling, Sr., has a documented lineage to Elder William Brewster, who arrived in America on the Mayflower, and it is used as a sample lineage.^[13]

Linus Pauling spent his first year living in a one-room apartment with his parents in Portland. In 1902, after his sister Pauline was born, Pauling's parents decided to move out of the city.^[14] They were crowded in their apartment, but could not afford more spacious living quarters in Portland. Lucy stayed with her husband's parents in Lake Oswego, while Herman searched for new housing. Herman brought the family to Salem, where he took up a job as a traveling salesman for the Skidmore Drug Company. Within a year of Lucile's birth in 1904, Herman Pauling moved his family to Oswego, where he opened his own drugstore.^[14] The business climate in Oswego was poor, so he moved his family to Condon in 1905.^[15] By 1909, Herman Pauling was suffering from poor health and had regular sharp pains in his abdomen. His health worsened in the coming months and he finally died of a perforated ulcer on June 11, 1910, leaving Lucy to care for Linus, Lucile and Pauline.^[16]

At age nine, Linus was a voracious reader. On May 12, 1910 his father wrote a letter to The Oregonian inviting suggestions of additional books to occupy his time.^[4] Pauling first planned to become a chemist after being amazed by experiments conducted with a small chemistry lab kit by his friend, Lloyd A. Jeffress.^[17] At high school, Pauling continued to conduct chemistry experiments, scavenging much of the equipment and material from an abandoned steel plant. With an older friend, Lloyd Simon, Pauling set up Palmon Laboratories. Operating from Simon's basement, the two approached local dairies to offer their services in performing butterfat samplings at cheap prices.
Dairymen were wary of trusting two boys with the task, and as such, the business ended in failure.^[18]

By the fall of 1916, Pauling was a 15-year-old high school senior with enough credits to enter Oregon State University (OSU), known then as Oregon Agricultural College.^[19] He did not have enough credits for two required American history courses that would satisfy the requirements for earning a high school diploma. He asked the school principal if he could take these courses concurrently during the spring semester, but the principal denied his request, and Pauling decided to leave the school in June without a diploma.^[20] His high school, Washington High School in Portland, awarded him the diploma 45 years later, after he had won two Nobel Prizes.^[21][22] During the summer, Pauling worked part-time at a grocery store, earning eight US dollars a week. His mother set him up with an interview with a Mr. Schwietzerhoff, the owner of a number of manufacturing plants in Portland. Pauling was hired as an apprentice machinist with a salary of 40 dollars per month. Pauling excelled at his job, and saw his salary soon raised to 50 dollars per month.^[23] In his spare time, he set up a photography laboratory with two friends and found business from a local photography company. He hoped that the business would earn him enough money to pay for his future college expenses.^[24] Pauling received a letter of admission from Oregon State University in September 1917 and immediately gave notice to his boss and told his mother of his plans.^[25]

Higher education

Pauling's graduation photo from Oregon State University, 1922

In his first semester, Pauling registered for two courses in chemistry, two in mathematics, mechanical drawing, introduction to mining and use of explosives, modern English prose, gymnastics and military drill.^[26] He was active in campus life and founded the school's chapter of the Delta Upsilon fraternity.^[27] After his second year, he planned to take a job in Portland to help support his mother, but the college offered him a position teaching quantitative analysis, a course he had just finished taking himself. He worked forty hours a week in the laboratory and classroom and earned $100 a month.^[28] This allowed him to continue his studies at the college.

In his last two years at school, Pauling became aware of the work of Gilbert N. Lewis and Irving Langmuir on the electronic structure of atoms and their bonding to form molecules.^[28] He decided to focus his research on how the physical and chemical properties of substances are related to the structure of the atoms of which they are composed, becoming one of the founders of the new science of quantum chemistry. Pauling began to neglect his studies in humanities and social sciences. He had also exhausted the course offerings in the physics and mathematics departments. Professor Samuel Graf selected Pauling to be his teaching assistant in a high-level mathematics course.^[29] During the winter of his senior year, Pauling was approached by the college to teach a chemistry course for home economics majors. It was in one of these classes that Pauling met his future wife, Ava Helen Miller.^[30]

In 1922, Pauling graduated from Oregon State University^[4] (known then as Oregon Agricultural College) with a degree in chemical engineering and went on to graduate school at the California Institute of Technology (Caltech) in Pasadena, California, under the guidance of Roscoe Dickinson and Richard Tolman.^[2] His graduate research involved the use of X-ray diffraction to determine the structure of crystals. He published seven papers on the crystal structure of minerals while he was at Caltech. He received his PhD in physical chemistry and mathematical physics,^[1] summa cum laude, in 1925.^[31]

Personal life

The Pauling children at a gathering in celebration of the 1954 Nobel Prizes in Stockholm, Sweden. Seated from left: Linus Pauling, Jr., Peter Pauling and Linda Pauling. Standing from left: an unidentified individual and Crellin Pauling

While teaching a class called "Chemistry for Home Economic Majors" at college,^[32] Pauling met his future wife, Ava Helen Miller and they married June 17, 1923. The marriage lasted until Ava Pauling's death in 1981 and produced three sons (Linus Jr., Peter and Edward Crellin) and a daughter (Linda).^[33] Pauling's sons went on to become scientists and researchers (Linus, a psychiatrist; Peter, who died in 2003, a crystallographer; and Edward Crellin, who died in 1997, a biologist; daughter Linda married the noted Caltech geologist and glaciologist Barclay Kamb).^[34]

Pauling was raised as a member of the Lutheran Church, but later joined the Unitarian Universalist Church. Two years before his death, in a published dialogue with Buddhist philosopher Daisaku Ikeda, Pauling publicly declared his atheism.^[35]

Career

Pauling was first exposed to the concepts of quantum mechanics while studying at Oregon State University. He later traveled to Europe on a Guggenheim Fellowship, which was awarded to him in 1926, to study under German physicist Arnold Sommerfeld in Munich, Danish physicist Niels Bohr in Copenhagen and Austrian physicist Erwin Schrödinger in Zürich. All three were experts in the new field of quantum mechanics and other branches of physics. Pauling became interested in how quantum mechanics might be applied in his chosen field of interest, the electronic structure of atoms and molecules. In Zürich, Pauling was also exposed to one of the first quantum mechanical analyses of bonding in the hydrogen molecule, done by Walter Heitler and Fritz London. Pauling devoted the two years of his European trip to this work and decided to make it the focus of his future research. He became one of the first scientists in the field of quantum chemistry and a pioneer in the application of quantum theory to the structure of molecules. He also joined Alpha Chi Sigma, the professional chemistry fraternity.

In 1927, Pauling took a new position as an assistant professor at Caltech in theoretical chemistry. He launched his faculty career with a very productive five years, continuing with his X-ray crystal studies and also performing quantum mechanical calculations on atoms and molecules. He published approximately fifty papers in those five years, and created the five rules now known as Pauling's rules. By 1929, he was promoted to associate professor, and by 1930, to full professor. In 1931, the American Chemical Society awarded Pauling the Langmuir Prize for the most significant work in pure science by a person 30 years of age or younger.^[36] The following year, Pauling published what he regarded as his most important paper, in which he first laid out the concept of hybridization of atomic orbitals and analyzed the tetravalency of the carbon atom.^[37]

At Caltech, Pauling struck up a close friendship with theoretical physicist Robert Oppenheimer, who was spending part of his research and teaching schedule away from U.C. Berkeley at Caltech every year. The two men planned to mount a joint attack on the nature of the chemical bond: apparently Oppenheimer would supply the mathematics and Pauling would interpret the results. Their relationship soured when Oppenheimer tried to pursue Pauling's wife, Ava Helen. Once, when Pauling was at work, Oppenheimer had come to their place and blurted out an invitation to Ava Helen to join him on a tryst in Mexico.^[38] She flatly refused, and reported the incident to Pauling. Disquieted by this strange chemistry, and her apparent nonchalance about the incident, he immediately cut off his relationship with Oppenheimer.

In the summer of 1930, Pauling made another European trip, during which he learned about the use of electrons in diffraction studies similar to the ones he had performed with X-rays. After returning, he built an electron diffraction instrument at Caltech with a student of his, L. O. Brockway, and used it to study the molecular structure of a large number of chemical substances.

Pauling introduced the concept of electronegativity in 1932. Using the various properties of molecules, such as the energy required to break bonds and the dipole moments of molecules, he established a scale and an associated numerical value for most of the elements – the Pauling Electronegativity Scale – which is useful in predicting the nature of bonds between atoms in molecules.

Nature of the chemical bond

In the late 1920s, Pauling began publishing papers on the nature of the chemical bond, leading to his famous textbook on the subject published in 1939. It is based primarily on his work in this area that he received the Nobel Prize in Chemistry in 1954 "for his research into the nature of the chemical bond and its application to the elucidation of the structure of complex substances". Pauling summarized his work on the chemical bond in The Nature of the Chemical Bond, one of the most influential chemistry books ever published.^[39] In the 30 years after its first edition was published in 1939, the book was cited more than 16,000 times. Even today, many modern scientific papers and articles in important journals cite this work, more than seventy years after the first publication.

Part of Pauling's work on the nature of the chemical bond led to his introduction of the concept of orbital hybridization.^[40] While it is normal to think of the electrons in an atom as being described by orbitals of types such as s and p, it turns out that in describing the bonding in molecules, it is better to construct functions that partake of some of the properties of each. Thus the one 2s and three 2p orbitals in a carbon atom can be combined to make four equivalent orbitals (called sp³ hybrid orbitals), which would be the appropriate orbitals to describe carbon compounds such as methane, or the 2s orbital may be combined with two of the 2p orbitals to make three equivalent orbitals (called sp² hybrid orbitals), with the remaining 2p orbital unhybridized, which would be the appropriate orbitals to describe certain unsaturated carbon compounds such as ethylene. Other hybridization schemes are also found in other types of molecules.

Another area which he explored was the relationship between ionic bonding, where electrons are transferred between atoms, and covalent bonding, where electrons are shared between atoms on an equal basis. Pauling showed that these were merely extremes, between which most actual cases of bonding fall. It was here especially that Pauling's electronegativity concept was particularly useful; the electronegativity difference between a pair of atoms will be the surest predictor of the degree of ionicity of the bond.^[41]

The third of the topics that Pauling attacked under the overall heading of "the nature of the chemical bond" was the accounting of the structure of aromatic hydrocarbons, particularly the prototype, benzene.^[42] The best description of benzene had been made by the German chemist Friedrich Kekulé. He had treated it as a rapid interconversion between two structures, each with alternating single and double bonds, but with the double bonds of one structure in the locations where the single bonds were in the other. Pauling showed that a proper description based on quantum mechanics was an intermediate structure which was a blend of each. The structure was a superposition of structures rather than a rapid interconversion between them. The name "resonance" was later applied to this phenomenon.^[43] In a sense, this phenomenon resembles that of hybridization, described earlier, because it involves combining more than one electronic structure to achieve an intermediate result.

Biological molecules

An alpha helix in ultra-high-resolution electron density contours, with O atoms in red, N atoms in blue, and hydrogen bonds as green dotted lines (PDB file 2NRL, 17-32).

In the mid-1930s, Pauling, strongly influenced by the biologically oriented funding priorities of the Rockefeller Foundation's Warren Weaver, decided to strike out into new areas of interest. Although Pauling's early interest had focused almost exclusively on inorganic molecular structures, he had occasionally thought about molecules of biological importance, in part because of Caltech's growing strength in biology. Pauling interacted with such great biologists as Thomas Hunt Morgan, Theodosius Dobzhanski, Calvin Bridges and Alfred Sturtevant. His early work in this area included studies of the structure of hemoglobin. He demonstrated that the hemoglobin molecule changes structure when it gains or loses an oxygen atom. As a result of this observation, he decided to conduct a more thorough study of protein structure in general. He returned to his earlier use of X-ray diffraction analysis. But protein structures were far less amenable to this technique than the crystalline minerals of his former work. The best X-ray pictures of proteins in the 1930s had been made by the British crystallographer William Astbury, but when Pauling tried, in 1937, to account for Astbury's observations quantum mechanically, he could not.

It took eleven years for Pauling to explain the problem: his mathematical analysis was correct, but Astbury's pictures were taken in such a way that the protein molecules were tilted from their expected positions. Pauling had formulated a model for the structure of hemoglobin in which atoms were arranged in a helical pattern, and applied this idea to proteins in general.

In 1951, based on the structures of amino acids and peptides and the planar nature of the peptide bond, Pauling, Robert Corey and Herman Branson correctly proposed the alpha helix and beta sheet as the primary structural motifs in protein secondary structure.^[44] This work exemplified Pauling's ability to think unconventionally; central to the structure was the unorthodox assumption that one turn of the helix may well contain a non-integer number of amino acid residues; for the alpha helix it is 3.7 amino acid residues per turn.

Pauling then proposed that deoxyribonucleic acid (DNA) was a triple helix;^[45][46] his model contained several basic mistakes, including a proposal of neutral phosphate groups, an idea that conflicted with the acidity of DNA. Sir Lawrence Bragg had been disappointed that Pauling had won the race to find the alpha helix structure of proteins. Bragg's team had made a fundamental error in making their models of protein by not recognizing the planar nature of the peptide bond. When it was learned at the Cavendish Laboratory that Pauling was working on molecular models of the structure of DNA, James Watson and Francis Crick were allowed to make a molecular model of DNA. They later benefited from unpublished data from Maurice Wilkins and Rosalind Franklin at King's College which showed evidence for a helix and planar base stacking along the helix axis. Early in 1953 Watson and Crick proposed a correct structure for the DNA double helix. Pauling later cited several reasons to explain how he had been misled about the structure of DNA, among them misleading density data and the lack of high quality X-ray diffraction photographs. During the time Pauling was researching the problem, Rosalind Franklin in England was creating the world's best images. They were key to Watson's and Crick's success. Pauling did not see them before devising his mistaken DNA structure, although his assistant Robert Corey did see at least some of them, while taking Pauling's place at a summer 1952 protein conference in England. Pauling had been prevented from attending because his passport was withheld by the State Department on suspicion that he had Communist sympathies. This led to the legend that Pauling missed the structure of DNA because of the politics of the day (this was at the start of the McCarthy period in the United States).^[47] Politics did not play a critical role. Not only did Corey see the images at the time, but Pauling himself regained his passport within a few weeks and toured English laboratories well before writing his DNA paper. He had ample opportunity to visit Franklin's lab and see her work, but chose not to.^[48]

Pauling also studied enzyme reactions and was among the first to point out that enzymes bring about reactions by stabilizing the transition state of the reaction, a view which is central to understanding their mechanism of action. He was also among the first scientists to postulate that the binding of antibodies to antigens would be due to a complementarity between their structures. Along the same lines, with the physicist turned biologist Max Delbrück, he wrote an early paper arguing that DNA replication was likely to be due to complementarity, rather than similarity, as suggested by a few researchers. This was made clear in the model of the structure of DNA that Watson and Crick discovered.

Molecular genetics

In November 1949, Linus Pauling, Harvey Itano, S. J. Singer and Ibert Wells published "Sickle Cell Anemia, a Molecular Disease"^[49] in the journal Science. It was the first proof of a human disease caused by an abnormal protein, and sickle cell anemia became the first disease understood at the molecular level. Using electrophoresis, they demonstrated that individuals with sickle cell disease had a modified form of hemoglobin in their red blood cells, and that individuals with sickle cell trait had both the normal and abnormal forms of hemoglobin. This was also the first demonstration that Mendelian inheritance determined the specific physical properties of proteins, not simply their presence or absence – the dawn of molecular genetics.

Activism

Pauling had been practically apolitical until World War II, but the aftermath of the war and his wife's pacifism changed his life profoundly, and he became a peace activist. During the beginning of the Manhattan Project, Robert Oppenheimer invited him to be in charge of the Chemistry division of the project, but he declined, not wanting to uproot his family. He did work on other projects that had military applications, such as explosives, rocket propellants, an oxygen meter for submarines and the patent of an armor-piercing shell; he was awarded a Presidential Medal of Merit.^[50][51] In 1946, he joined the Emergency Committee of Atomic Scientists, chaired by Albert Einstein.^[52] Its mission was to warn the public of the dangers associated with the development of nuclear weapons. His political activism prompted the U.S. State Department to deny him a passport in 1952, when he was invited to speak at a scientific conference in London.^[53][54] In a speech before the US Senate on June 6 of the same year, Senator Wayne Morse publicly denounced the action of the State Department, and urged the Passport Division to reverse its decision. Pauling and his wife Ava were issued a “limited passport” to attend the aforementioned conference in England.^[55][56] His passport was restored in 1954, shortly before the ceremony in Stockholm where he received his first Nobel Prize. Joining Einstein, Bertrand Russell and eight other leading scientists and intellectuals, he signed the Russell-Einstein Manifesto in 1955.^[57]

In 1958, Pauling joined a petition drive in cooperation with the founders of the St. Louis Citizen's Committee for Nuclear Information (CNI). This group, headed by Washington University in St. Louis professors Barry Commoner, Eric Reiss, M. W. Friedlander and John Fowler, set up a study of radioactive strontium-90 in the baby teeth of children across North America. The "Baby Tooth Survey," headed by Dr Louise Reiss, demonstrated conclusively in 1961 that above-ground nuclear testing posed significant public health risks in the form of radioactive fallout spread primarily via milk from cows that had ingested contaminated grass.^[58][59][60] Pauling also participated in a public debate with the atomic physicist Edward Teller about the actual probability of fallout causing mutations.^[61] In 1958, Pauling and his wife presented the United Nations with the petition signed by more than 11,000 scientists calling for an end to the testing of nuclear weapons. Public pressure and the frightening results of the CNI research subsequently led to a moratorium on above-ground nuclear weapons testing, followed by the Partial Test Ban Treaty, signed in 1963 by John F. Kennedy and Nikita Khrushchev. On the day that the treaty went into force, the Nobel Prize Committee awarded Pauling the Nobel Peace Prize, describing him as "Linus Carl Pauling, who ever since 1946 has campaigned ceaselessly, not only against nuclear weapons tests, not only against the spread of these armaments, not only against their very use, but against all warfare as a means of solving international conflicts."^[62] The Committee for Nuclear Information was never credited for its significant contribution to the test ban, nor was the ground-breaking research conducted by Dr Reiss and the "Baby Tooth Survey". The Caltech Chemistry Department, wary of his political views, did not even formally congratulate him. They did throw him a small party, showing they were more appreciative and sympathetic toward his work on radiation mutation. At Caltech he founded Sigma Xi's (The Scientific Research Society) chapter at the school, as he had previously been a member of that organization. He continued his peace activism in the following years co-founding the International League of Humanists in 1974. He was president of the scientific advisory board of the World Union for Protection of Life and also one of the signatories of the Dubrovnik-Philadelphia Statement.

During the 1960s, President Lyndon Johnson’s policy of increasing America’s involvement in the Vietnam War caused an antiwar movement that the Paulings joined with enthusiasm. Pauling denounced the war as unnecessary and unconstitutional. He made speeches, signed protest letters and communicated personally with the North Vietnamese leader, Ho Chi Minh, and gave the lengthy written response to President Johnson. His efforts were ignored by the government.^[63] By the time Pauling turned 65 in 1966, he was without a research group or a big scientific issue to focus on. A new generation of more radical, younger activists would march, petition, and lead the movement against the Vietnam War.

Many of Pauling's critics, including scientists who appreciated the contributions that he had made in chemistry, disagreed with his political positions and saw him as a naive spokesman for Soviet communism. He was ordered to appear before the Senate Internal Security Subcommittee, which termed him "the number one scientific name in virtually every major activity of the Communist peace offensive in this country." A headline in Life magazine characterized his 1962 Nobel Prize as "A Weird Insult from Norway". Pauling was awarded the International Lenin Peace Prize by the USSR in 1970.^[64]

Contretemps with William F. Buckley, National Review

After Pauling had won the Nobel Peace Prize and the Lenin Peace Prize, he became a frequent target of The National Review magazine; particularly, in an article entitled "The Collaborators" in the magazine's July 17, 1962 issue. Pauling was referred to not only as a collaborator, but as a "fellow traveler" with proponents of Soviet-style communism. These National Review articles set off a three-year legal battle in the form of federal libel case. In 1965, Pauling sued the magazine, its publisher William Rusher, and its editor William F. Buckley, Jr for $1 million. Subsequently, he lost both his suit and the 1968 appeal.^{[65][66][67][68]}

Molecular medicine, medical research, and vitamin C advocacy

Pauling's book, How to Live Longer and Feel Better, advocated the very high intake of Vitamin C.

In 1941, at age 40, Pauling was diagnosed with Bright's disease, a renal disease. Following the recommendations of Thomas Addis, Pauling was able to control the disease with Addis' then-unusual low-protein salt-free diet and vitamin supplements.^[69]

In 1951, Pauling gave a lecture entitled "Molecular Medicine".^[70] In the late 1950s, Pauling worked on the role of enzymes in brain function, believing that mental illness may be partly caused by enzyme dysfunction. In 1965 Pauling read Niacin Therapy in Psychiatry by Abram Hoffer and theorized vitamins might have important biochemical effects unrelated to their prevention of associated deficiency diseases.^[71] In 1968 Pauling published a brief paper in Science entitled "Orthomolecular psychiatry"^[72] that gave name and principle to the popular but controversial megavitamin therapy movement of the 1970s. Pauling coined the term "orthomolecular" to refer to the practice of varying the concentration of substances normally present in the body to prevent and treat disease. His ideas formed the basis of orthomolecular medicine, which is not generally practiced by conventional medical professionals and has been strongly criticized.^[73][74] His promotion of dietary supplements has also been criticized. In a 2013 article in The Atlantic, pediatrician Paul Offit wrote that although Pauling was "so spectacularly right" that he won two Nobel Prizes, Pauling's late-career assertions about the benefits of dietary supplements were "so spectacularly wrong that he was arguably the world's greatest quack."^[75]

Pauling's work on vitamin C in his later years generated much controversy. He was first introduced to the concept of high-dose vitamin C by biochemist Irwin Stone in 1966. After becoming convinced of its worth, Pauling took 3 grams of vitamin C every day to prevent colds.^[4] Excited by his own perceived results, he researched the clinical literature and published Vitamin C and the Common Cold in 1970. He began a long clinical collaboration with the British cancer surgeon Ewan Cameron in 1971 on the use of intravenous and oral vitamin C as cancer therapy for terminal patients.^[76] Cameron and Pauling wrote many technical papers and a popular book, Cancer and Vitamin C, that discussed their observations. Pauling made vitamin C popular with the public and eventually published two studies of a group of 100 allegedly terminal patients that claimed vitamin C increased survival by as much as four times compared to untreated patients.^[77][78] A re-evaluation of the claims in 1982 found that the patient groups were not actually comparable, with the vitamin C group being less sick on entry to the study, and judged to be "terminal" much earlier than the comparison group.^[79] Later clinical trials conducted by the Mayo Clinic also concluded that high-dose (10,000 mg) vitamin C was no better than placebo at treating cancer and that there was no benefit to high-dose vitamin C.^[80][81][82] The failure of the clinical trials to demonstrate any benefit resulted in the conclusion that vitamin C was not effective in treating cancer; the medical establishment concluding that his claims that vitamin C could prevent colds or treat cancer were quackery.^[4][83]
Pauling denounced the conclusions of these studies and handling of the final study as "fraud and deliberate misrepresentation",^[84][85] and criticized the studies for using oral, rather than intravenous vitamin C^[86] (which was the dosing method used for the first ten days of Pauling's original study^[83]). Pauling also criticised the Mayo clinic studies because the controls were taking vitamin C during the trial, and because the duration of the treatment with vitamin C was short; Pauling advocated continued high dose vitamin C for the rest of the cancer patient's life whereas the Mayo clinic patients in the second trial were treated with vitamin C for a median of 2.5 months.^[87] The results were publicly debated at length with considerable acrimony between Pauling and Cameron, and Moertel (the lead author of the Mayo Clinic studies), with accusations of misconduct and scientific incompetence on both sides. Ultimately the negative findings of the Mayo Clinic studies ended general interest in vitamin C as a treatment for cancer.^[85] Despite this, Pauling continued to promote vitamin C for treating cancer and the common cold, working with The Institutes for the Achievement of Human Potential to use vitamin C in the treatment of brain-injured children.^[88] He later collaborated with the Canadian physician Abram Hoffer on a micronutrient regime, including high-dose vitamin C, as adjunctive cancer therapy.^[89] A 2009 review also noted differences between the studies, such as the Mayo clinic not using intravenous Vitamin C, and suggested further studies into the role of vitamin C when given intravenously.^[90] Currently, the available evidence does not support a role for high dose vitamin C in the treatment of cancer.^[91]

With Arthur B. Robinson and another colleague, Pauling founded the Institute of Orthomolecular Medicine in Menlo Park, California, in 1973, which was soon renamed the Linus Pauling Institute of Science and Medicine. Pauling directed research on vitamin C, but also continued his theoretical work in chemistry and physics until his death. In his last years, he became especially interested in the possible role of vitamin C in preventing atherosclerosis and published three case reports on the use of lysine and vitamin C to relieve angina pectoris. In 1996, the Linus Pauling Institute moved from Palo Alto, California, to Corvallis, Oregon, to become part of Oregon State University, where it continues to conduct research on micronutrients, phytochemicals (chemicals from plants), and other constituents of the diet in preventing and treating disease. Several researchers that had previously worked at the Linus Pauling Institute in Palo Alto, including the assistant director of research, moved on to form the Genetic Information Research Institute.

Structure of the atomic nucleus

On September 16, 1952, Pauling opened a new research notebook with the words "I have decided to attack the problem of the structure of nuclei."^[92] On October 15, 1965, Pauling published his Close-Packed Spheron Model of the atomic nucleus in two well respected journals, Science and the Proceedings of the National Academy of Sciences.^[93] For nearly three decades, until his death in 1994, Pauling published numerous papers on his spheron cluster model.^{[94][95][96][97][98][99]}

The basic idea behind Pauling's spheron model is that a nucleus can be viewed as a set of "clusters of nucleons". The basic nucleon clusters include the deuteron [np], helion [pnp], and triton [npn]. Even–even nuclei are described as being composed of clusters of alpha particles, as has often been done for light nuclei.^{[citation needed]} Pauling attempted to derive the shell structure of nuclei from pure geometrical considerations related to Platonic solids rather than starting from an independent particle model as in the usual shell model. In an interview given in 1990 Pauling commented on his model:^[100]

Now recently, I have been trying to determine detailed structures of atomic nuclei by analyzing the ground state and excited state vibrational bends, as observed experimentally. From reading the physics literature, Physical Review Letters and other journals, I know that many physicists are interested in atomic nuclei, but none of them, so far as I have been able to discover, has been attacking the problem in the same way that I attack it. So I just move along at my own speed, making calculations...

Legacy

Pauling died of prostate cancer on August 19, 1994, at 19:20 at home in Big Sur, California. He was 93 years old.^[101][102] A grave marker for him is in Oswego Pioneer Cemetery in Lake Oswego, Oregon.^[102][103] Pauling’s ashes, along with those of his wife, were moved from Big Sur to the Oswego Pioneer Cemetery in 2005.^[104]

Pauling was included in a list of the 20 greatest scientists of all time by the magazine New Scientist, with Albert Einstein being the only other scientist from the 20th century on the list. Pauling is notable for the diversity of his interests: quantum mechanics, inorganic chemistry, organic chemistry, protein structure, molecular biology, and medicine. In all these fields, and especially on the boundaries between them, he made decisive contributions. His work on chemical bonding marks the beginning of modern quantum chemistry, and many of his contributions like hybridization and electronegativity have become part of standard chemistry textbooks. While his valence bond approach fell short of accounting quantitatively for some of the characteristics of molecules, such as the photoelectron spectra of many molecules, and would later be eclipsed by the molecular orbital theory of Robert Mulliken, Valence Bond Theory still competes, in its modern form, with Molecular Orbital Theory and density functional theory (DFT) for describing the chemical phenomena.^[105] Pauling's work on crystal structure contributed significantly to the prediction and elucidation of the structures of complex minerals and compounds.^{[citation needed]} His discovery of the alpha helix and beta sheet is a fundamental foundation for the study of protein structure.^{[citation needed]}

Francis Crick acknowledged Pauling as the "father of molecular biology"^[106] His discovery of sickle cell anemia as a "molecular disease" opened the way toward examining genetically acquired mutations at a molecular level.^{[citation needed]}

Pauling's work on the molecular basis of disease and its treatment is being carried on by a number of researchers, notably those at the Linus Pauling Institute, which lists a dozen principal investigators and faculty who study the role of micronutrients and phytochemicals in health and disease.

Items named after Pauling include Pauling Street in Foothill Ranch, California,^[107] Linus Pauling Drive in Hercules, California, Linus and Ava Helen Pauling Hall at Soka University of America in Aliso Viejo, California, Linus Pauling Middle School in Corvallis, Oregon, and Pauling Field, a small airfield located in Condon, Oregon, where Pauling spent his youth. Additionally, the Linus Pauling Institute^[108] and also a wing of The Valley Library at Oregon State University bear his name. There is a psychedelic rock band in Houston, Texas, named The Linus Pauling Quartet.

The Caltech Chemistry Department renamed room 22 of Gates Hall the Linus Pauling Lecture Hall, since Linus spent so much time there.

Linus Torvalds, developer of the Linux kernel, is named after Pauling.^[109]

On March 6, 2008, the United States Postal Service released a 41 cent stamp honoring Pauling designed by artist Victor Stabin.^[110][111] His description reads: "A remarkably versatile scientist, structural chemist Linus Pauling (1901–1994) won the 1954 Nobel Prize in Chemistry for determining the nature of the chemical bond linking atoms into molecules. His work in establishing the field of molecular biology; his studies of hemoglobin led to the classification of sickle cell anemia as a molecular disease."^{[citation needed]} The other scientists on this sheet include Gerty Cori, biochemist, Edwin Hubble, astronomer, and John Bardeen, physicist.

California Governor Arnold Schwarzenegger and First Lady Maria Shriver announced on May 28, 2008 that Pauling would be inducted into the California Hall of Fame, located at The California Museum for History, Women and the Arts. The induction ceremony took place December 15, 2008. Pauling's son was asked to accept the honor in his place.

Nobel laureate Peter Agre has said that Linus Pauling inspired him.^[112]

Quasicrystals

Pauling was a stubborn opponent of the idea of quasicrystals, relentlessly attacking Shechtman; Pauling is quoted as saying "There is no such thing as quasicrystals, only quasi-scientists."^[113] Shechtman was awarded the Nobel Prize in Chemistry in 2011 for his work on quasicrystals.

Honors and awards

Pauling received numerous awards and honors during his career, including the following:^[114][115]

• 1931 ACS Award in Pure Chemistry ^[116]
• 1931 Irving Langmuir Award, American Chemical Society.^[114][115]
• 1941 Nichols Medal, New York Section, American Chemical Society.^[114]
• 1946 Willard Gibbs Award, Chicago section of the American Chemical Society.^[115]
• 1947 Davy Medal, Royal Society.^[114][115]
• 1947 T. W. Richards Medal, Northeastern Section of the American Chemical Society.^[115]
• 1948 Presidential Medal for Merit by President Harry S. Truman of the United States.^[114][115]
• 1948 Elected a Foreign Member of the Royal Society of London (ForMemRS)^[4]
• 1951 Gilbert N. Lewis medal, California section of the American Chemical Society.^[115]
• 1952 Pasteur Medal, Biochemical Society of France.^[114]
• 1954 Nobel Prize in Chemistry.^[114][115]
• 1955 Addis Medal, National Nephrosis Foundation.^[114][115]
• 1955 John Phillips Memorial Award, American College of Physicians.^[114][115]
• 1956 Avogadro Medal, Italian Academy of Science.^[114][115]
• 1957 Paul Sabatier Medal.
• 1957 Pierre Fermat Medal in Mathematics (awarded for only the sixth time in three centuries).^{[114][115][117]}
• 1957 International Grotius Medal.^[114]
• 1961 Humanist of the Year, American Humanist Association.
• 1961 Gandhi Peace Award by Promoting Enduring Peace.^[118]
• 1962 Nobel Peace Prize.^[114][115]
• 1965 Medal, Academy of the Rumanian People's Republic.^[114]
• 1966 Linus Pauling Award.^[114]
• 1966 Silver Medal, Institute of France.^[114]
• 1966 Supreme Peace Sponsor, World Fellowship of Religion.^[114]
• 1967 Washington A. Roebling Medal, Mineralogical Society of America.^[115]
• 1972 Lenin Peace Prize.^[114]
• 1974 National Medal of Science by President Gerald R. Ford of the United States.^[115]
• 1978 Lomonosov Gold Medal, Presidium of the Academy of the USSR.^[114][115]
• 1979 NAS Award in Chemical Sciences, National Academy of Sciences.^[114][119]
• 1981 John K. Lattimer Award, American Urological Association.^[115]
• 1984 Priestley Medal, American Chemical Society.^[114][115]
• 1984 Award for Chemistry, Arthur M. Sackler Foundation.^[114]
• 1986 Lavoisier Medal by Fondation de la Maison de la Chimie.^[115]
• 1987 Award in Chemical Education, American Chemical Society.^[114]
• 1989 Vannevar Bush Award, National Science Board.^[114][115]
• 1990 Richard C. Tolman Medal, American Chemical Society Southern California Section.^[114]
• 1992 Daisaku Ikeda Medal, Soka Gakkai International^[115]
• 2008 "American Scientists" U.S. postage stamp series, $0.41, for his sickle cell disease work.^[120]

Publications

Books

Library resources about Linus Pauling
Resources in your library Resources in other libraries
By Linus Pauling
Online books Resources in your library Resources in other libraries

• — (1939). The Nature of the Chemical Bond and the Structure of Molecules and Crystals. Cornell University Press. 
• — (1947). General Chemistry: An Introduction to Descriptive Chemistry and Modern Chemical Theory. W. H. Freeman. 
  • Greatly revised and expanded in 1947, 1953, and 1970. Reprinted by Dover Publications in 1988.
• — Hayward, Roger (1964). The Architecture of Molecules. San Francisco: Freeman. ISBN 978-0716701583. 
  • Manuscript notes and typescripts (clear images)
• — (1958). No more war!. Dodd, Mead & Co. ISBN 978-1124119663. 
• — (1977). Vitamin C, the Common Cold and the Flu. W.H. Freeman. ISBN 0-7167-0360-2. 
• — (1987). How to Live Longer and Feel Better. Avon. ISBN 0-380-70289-4. 
• — Wilson, E. B. (1985). Introduction to Quantum Mechanics with Applications to Chemistry. Dover. ISBN 0-486-64871-0. 
• Cameron, E.; — (1993). Cancer and Vitamin C: A Discussion of the Nature, Causes, Prevention, and Treatment of Cancer With Special Reference to the Value of Vitamin C. Camino. ISBN 0-940159-21-X. 
• — (1998). Linus Pauling On Peace: A Scientist Speaks Out on Humanism and World Survival. Rising Star Press. ISBN 0-933670-03-6. 
• Hoffer, Abram; — (2004). Healing Cancer: Complementary Vitamin & Drug Treatments. Toronto: CCNM Press. ISBN 978-1897025116. 
• Ikeda, Daisaku; — (2008). A Lifelong Quest for Peace: A Dialogue. Richard L. Gage (ed., trans.). London: I. B. Tauris. ISBN 978-1-84511-889-1. 

Journal articles

• Pauling, L. (1927). "The Theoretical Prediction of the Physical Properties of Many-Electron Atoms and Ions. Mole Refraction, Diamagnetic Susceptibility, and Extension in Space". Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 114 (767): 181. Bibcode:1927RSPSA.114..181P. doi:10.1098/rspa.1927.0035.  edit
• Pauling, L. (1929). "The Principles Determining the Structure of Complex Ionic Crystals". Journal of the American Chemical Society 51 (4): 1010. doi:10.1021/ja01379a006.  edit
• Pauling, L. (1931). "The Nature of the Chemical Bond. Application of Results Obtained from the Quantum Mechanics and from a Theory of Paramagnetic Susceptibility to the Structure of Molecules". Journal of the American Chemical Society 53 (4): 1367. doi:10.1021/ja01355a027.  edit
• Pauling, L. (1931). "The Nature of the Chemical Bond. Ii. The One-Electron Bond and the Three-Electron Bond". Journal of the American Chemical Society 53 (9): 3225. doi:10.1021/ja01360a004.  edit
• Pauling, L. (1932). "The Nature of the Chemical Bond. Iii. The Transition from One Extreme Bond Type to Another". Journal of the American Chemical Society 54 (3): 988. doi:10.1021/ja01342a022.  edit
• Pauling, L. (1932). "The Nature of the Chemical Bond. Iv. The Energy of Single Bonds and the Relative Electronegativity of Atoms". Journal of the American Chemical Society 54 (9): 3570. doi:10.1021/ja01348a011.  edit
• Pauling, L.; Wheland, G. W. (1933). "The Nature of the Chemical Bond. V. The Quantum-Mechanical Calculation of the Resonance Energy of Benzene and Naphthalene and the Hydrocarbon Free Radicals". The Journal of Chemical Physics 1 (6): 362. doi:10.1063/1.1749304.  edit
• Pauling, L. (1935). "The Structure and Entropy of Ice and of Other Crystals with Some Randomness of Atomic Arrangement". Journal of the American Chemical Society 57 (12): 2680. doi:10.1021/ja01315a102.  edit
• Pauling, L. (1940). "A Theory of the Structure and Process of Formation of Antibodies*". Journal of the American Chemical Society 62 (10): 2643. doi:10.1021/ja01867a018.  edit
• Pauling, L. (1947). "Atomic Radii and Interatomic Distances in Metals". Journal of the American Chemical Society 69 (3): 542. doi:10.1021/ja01195a024.  edit
• Pauling, L.; Itano, H. A.; Singer, S. J.; Wells, I. C. (1949). "Sickle Cell Anemia, a Molecular Disease". Science 110 (2865): 543–548. doi:10.1126/science.110.2865.543. PMID 15395398.  edit
• Pauling, L.; Corey, R. B.; Branson, H. R. (1951). "The structure of proteins: Two hydrogen-bonded helical configurations of the polypeptide chain". Proceedings of the National Academy of Sciences 37 (4): 205–11. doi:10.1073/pnas.37.4.205. PMC 1063337. PMID 14816373.  edit

Irène Joliot-Curie

From Wikipedia, the free encyclopedia

Irène Joliot-Curie
Born	(1897-09-12)12 September 1897 Paris, France
Died	17 March 1956(1956-03-17) (aged 58) Paris, France
Residence	Paris, France
Citizenship	French
Nationality	French, of French and Polish descent
Fields	Chemistry
Alma mater	Sorbonne
Doctoral advisor	Paul Langevin
Doctoral students	her children (see below)
Notable awards	Nobel Prize for Chemistry (1935)
Spouse	Frédéric Joliot-Curie (1900–)
Children	Hélène Langevin-Joliot (b. 1927) Pierre Joliot (b. 1932)

Irène Joliot-Curie (12 September 1897 – 17 March 1956) was a French scientist, the daughter of Marie Skłodowska-Curie and Pierre Curie and the wife of Frédéric Joliot-Curie. Jointly with her husband, Joliot-Curie was awarded the Nobel Prize for chemistry in 1935 for their discovery of artificial radioactivity. This made the Curies the family with the most Nobel laureates to date.^[1] Both children of the Joliot-Curies, Hélène and Pierre, are also esteemed scientists.^[2]

Biography

Early life and education

Curie was born in Paris, France. After a year of traditional education, which began when she was 10 years old, her parents realized her obvious mathematical talent and decided that Irène’s academic abilities needed a more challenging environment. Marie joined forces with a number of eminent French scholars, including the prominent French physicist Paul Langevin to form “The Cooperative,” a private gathering of some of the most distinguished academics in France. Each contributed to educating one another’s children in their respective homes. The curriculum of The Cooperative was varied and included not only the principles of science and scientific research but such diverse subjects as Chinese and sculpture and with great emphasis placed on self-expression and play.^[3]

This arrangement lasted for two years after which Curie re-entered a more orthodox learning environment at the Collège Sévigné in central Paris from 1912 to 1914 and then onto the Faculty of Science at the Sorbonne, to complete her Baccalaureate. Her studies at the Faculty of Science were interrupted by World War I.

World War I

Initially, Curie was taken to the countryside but a year later when she turned 18 she was re-united with her mother, running the 20 mobile field hospitals that Marie had established. The hospitals were equipped with primitive X-ray equipment made possible by the Curies’ radiochemical research. This technology greatly assisted doctors to locate shrapnel in wounded soldiers, but it was crude and led to both Marie and Irène, who were serving as nurse radiographers, suffering large doses of radiation exposure. Both would eventually die from the consequences of accumulated radiation exposure over their professional life.

After the War, Curie returned to Paris to study at the Radium Institute, which had been built by her parents. The institute was completed in 1914 but remained empty during the war. Her doctoral thesis was concerned with the alpha rays of polonium, the element discovered by her parents (along with radium) and named after Marie’s country of birth, Poland. Curie became Doctor of Science in 1925.

Research

Irene and Marie Curie in 1925

As she neared the end of her doctorate in 1924 she was asked to teach the precise laboratory techniques required for radiochemical research to the young chemical engineer Frédéric Joliot whom she would later come to wed. From 1928 Joliot-Curie and her husband Frédéric combined their research interests on the study of atomic nuclei. Though their experiments identified both the positron and the neutron, they failed to interpret the significance of the results and the discoveries were later claimed by Carl David Anderson and James Chadwick respectively. These discoveries would have secured greatness indeed, as together with J. J. Thomson's discovery of the electron in 1897, they finally replaced John Dalton’s theory of atoms being solid spherical particles.

Finally, in 1934 they made the discovery that sealed their place in scientific history. Building on the work of Marie and Pierre, who had isolated naturally occurring radioactive elements, Joliot-Curies realized the alchemist’s dream of turning one element into another, creating radioactive nitrogen from boron and then radioactive isotopes of phosphorus from aluminum and silicon from magnesium. For example, irradiating the main natural and stable isotope of aluminum with alpha particles (i.e. helium nuclei) results in an unstable isotope of phosphorus : ²⁷Al + ⁴He → ³⁰P + ¹n.^[4][5][6] By now the application of radioactive materials for use in medicine was growing and this discovery led to an ability to create radioactive materials quickly, cheaply and plentifully. The Nobel Prize for chemistry in 1935 brought with it fame and recognition from the scientific community and Joliot-Curie was awarded a professorship at the Faculty of Science.

Irène’s group pioneered research into radium nuclei that led a separate group of German physicists, led by Otto Hahn, Lise Meitner, and Fritz Strassman, to discover nuclear fission; the splitting of the nucleus itself and the vast amounts of energy emitted as a result.

The years of working so closely with such deadly materials finally caught up with Joliot-Curie and she was diagnosed with leukemia. She had been accidentally exposed to polonium when a sealed capsule of the element exploded on her laboratory bench in 1946. Treatment with antibiotics and a series of operations did relieve her suffering temporarily but her condition continued to deteriorate. Despite this Joliot-Curie continued to work and in 1955 drew up plans for new physics laboratories at the Universitie d’Orsay, south of Paris.

Political views

The Joliot-Curies had become increasingly aware of the growth of the fascist movement. They opposed its ideals and joined the Socialist Party in 1934, the Comité de vigilance des intellectuels antifascistes a year later, and in 1936 actively supported the Republicans in the Spanish Civil War. In the same year, Joliot-Curie was appointed Undersecretary of State for Scientific Research by the French government, in which capacity she helped in founding the Centre National de la Recherche Scientifique.

The Joliot-Curies had continued Pierre and Marie’s policy of publishing all of their work for the benefit of the global scientific community, but afraid of the danger that might result should it be developed for military use, they stopped. On 30 October 1939 they placed all of their documentation on nuclear fission in the vaults of the French Academy of Sciences, where it remained until 1949.
Joliot-Curie's political career continued after the war and she became a commissioner in the Commissariat à l'énergie atomique. However, she still found time for scientific work and in 1946 became director of her mother’s Institut du Radium (Radium Institute).

Joliot-Curie became actively involved in promoting women’s education, serving on the National Committee of the Union of French Women (Comité National de l'Union des Femmes Françaises) and the World Peace Council. Joliot-Curies were given memberships to the French Légion d'honneur; Irène as an officer and Frédéric as a commissioner, recognising his earlier work for the resistance.

Personal life

The Joliot-Curies in the 1940s

Irène and Frédéric hyphenated their surnames to Joliot-Curie after they married in 1926. Eleven months later, their daughter Hélène was born; she would also become a noted physicist. Their son, Pierre, a biologist, was born in 1932.

During World War II Joliot-Curie contracted tuberculosis and was forced to spend several years convalescing in Switzerland. Concern for her own health together with the anguish of leaving her husband and children in occupied France was hard to bear and she did make several dangerous visits back to France, enduring detention by German troops at the Swiss border on more than one occasion. Finally, in 1944 Joliot-Curie judged it too dangerous for her family to remain in France and she took her children back to Switzerland.

In 1956, after a final convalescent period in the French Alps, Joliot-Curie was admitted to the Curie hospital in Paris, where she died on 17 March at the age of 58 from leukemia.^[7]

Joliot-Curie was an atheist.^[8][9]

Joliot-Curie's daughter, Hélène Langevin-Joliot, is a nuclear physicist and professor at the University of Paris; her son, Pierre Joliot, is a biochemist at Centre National de la Recherche Scientifique.

Notable honors

• Nobel Prize in Chemistry in 1935 for the discovery of artificial radioactivity with Frederic Joliot-Curie.
• Barnard College Gold Medal for Meritorious Service to Science 1940 with Frederic Joliot-Curie
• Officer of the Legion of Honor.^[10]