Everything about Linus Pauling totally explained
Linus Carl Pauling (
February 28,
1901 –
August 19,
1994) was an
American scientist,
peace activist,
author and
educator. He is considered one of the most influential
chemists of the
20th century and ranks among the most important scientists in history.
Pauling was one of the first scientists to work in the fields of
quantum chemistry,
molecular biology and
orthomolecular medicine. He is also a member of a small group of individuals who have been awarded more than one
Nobel Prize, one of only two people to receive them in different fields (the other was
Marie Curie) and the only person in that group to have been awarded each of his prizes without having to share it with another recipient.
Pauling was born and raised in Oregon. He attended
Oregon Agricultural College and graduated in 1922 with a degree in
chemical engineering. Pauling then went to the
California Institute of Technology (Caltech), where he received his
Ph. D in
physical chemistry and
mathematical physics in 1925. Two years later, he accepted a position at Caltech as an assistant professor in theoretical chemistry. In 1932, Pauling published a landmark paper, detailing his theory of
orbital hybridization and analyzed the
tetravalency of
carbon. That year, he also established the concept of
electronegativity and developed a
scale that would help predict the nature of chemical bonding. Pauling continued this work, but also began publishing papers on the structure of the atomic nucleus. In 1954, Pauling was awarded the
Nobel Prize in Chemistry. As a biochemist, Pauling conducted research with
X-ray crystallography and modeling in
crystal and
protein structures. This type of approach was used by English scientists to discover the
double helix structure of the
DNA molecule.
During the
Second World War, Pauling worked on military research and development. However, when the war ended he became particularly concerned about the further development and possible use of
atomic weapons and with the destruction inflicted on the world by war in general.
Ava Helen Pauling, Linus's wife, was a
pacifist and in time he came to share her views. Pauling soon began to express his concerns with the effects of
nuclear fallout and in 1962, was awarded the
Nobel Peace Prize for his campaign against above ground
nuclear testing. His beliefs were not without controversy at the time and he was criticized by some for his actions.
Pauling was also successful as an author and educator. His first book,
The Nature of the Chemical Bond (1939), is considered influential even to this day, as is his introductory
textbook,
General Chemistry (1949). Later in life, he became an advocate for greatly increased consumption of
vitamin C and other nutrients. He generalized his ideas to define
orthomolecular medicine, which is still regarded as
unorthodox by conventional
medicine. He popularized his concepts, analyses, research and insights in several successful but controversial books, such as
How to Live Longer and Feel Better in 1986. He died of prostate cancer on 19 August 1994.
Early life
Pauling was born in
Portland,
Oregon as the first born child to Herman Henry William Pauling (1876–1910) and Lucy Isabelle "Belle" Darling (1881–1926). He was named "Linus Carl", in honor of Lucy's father, Linus, and Herman's father, Carl. Herman and Lucy—then 23 and 18 years old, respectively—had met at a dinner party in
Condon. Six months later, the two got married.
Herman Pauling descended from South-German farmers, who had immigrated to a
German settlement in
Concordia,
Missouri. Carl Pauling moved his family to
California before settling in Oswego. There, he worked as an
ironmonger at a
foundry. After completing grammar school, Herman Pauling served as an apprentice to
druggist. Upon completion of his services, he became a wholesale drug salesman.
Pauling's mother, Lucy, of
Irish descent, was the daughter of Linus Wilson Darling, who had served as a
teacher,
farmer,
surveyor,
postmaster and
lawyer at different points of his life. Linus Darling was orphaned at age 11 and apprenticed under a
baker before becoming a schoolteacher. He fell in love with a young woman named Alice from
Turner,
Oregon, whom he eventually married. On
July 17,
1888, Alice gave birth to the couple's fifth child, but he was
stillborn. Less than a month later, she died, leaving Darling to take care of their four young daughters.
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. They were crowded in their apartment, but couldn't afford more spacious living quarters in Portland. Lucy stayed with her husband's parents in 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.
In 1909, Pauling's grandfather, Linus, divorced his second wife and married a young schoolteacher, almost the same age as his daughter Lucy. A few months later, he died of a
heart attack, brought on by complications from
nephritis. Meanwhile, Herman Pauling was suffering from poor health and had regular sharp pains in his
abdomen. Lucy's sister, Abbie, saw that Herman was dying and immediately called the family physician. The doctor gave Herman a sedative to reduce the pain, but it only offered temporary relief. His health worsened in the coming months and finally died of a perforated
ulcer on
June 11,
1910, leaving Lucy to care for Linus, Lucile and Pauline.
Linus was a voracious reader as a child, and at one point his father wrote a letter to
The Oregonian inviting suggestions of additional books to occupy his time. 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. In high school, Pauling continued to conduct chemistry experiments, borrowing 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 young adults approached local dairies to offer their services in performing butterfat samplings at cheap prices. Dairymen were wary of trusting two young boys with the task, and as such, the business ended as a failure.
By the fall of 1916, Pauling was a 15-year-old high school senior and had enough credits to enter Oregon Agricultural College (OAC, now known as
Oregon State University) in
Corvallis. However, he didn't have credit for two required American history courses that would satisfy his requirement to earn a
high school diploma. He asked the school principal if he could take these courses concurrently during the spring semester. The principal denied his request, and Pauling decided to leave the school in June without a diploma. His high school,
Washington High School in Portland, awarded him the diploma 45 years later, after he'd won two Nobel Prizes. During the summer, Pauling worked part-time at a grocery store, earning eight 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 a month. Pauling excelled at his job, and saw his salary increase to 50 dollars a month after being on the job for only a month. In his spare time, he set up a photography lab 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. Pauling received a letter of admission from OAC in September 1917 and immediately
gave notice to his boss and told his mother of his plans.
Higher education
In October 1917, Pauling entered Oregon Agricultural College and lived in a
boarding house on campus with his cousin Mervyn and another man, using the $200 he'd saved from odd jobs to finance his education. 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. Pauling fell in love with a freshman girl named Irene early in the school year. By the end of October, he'd used up $150 of his savings on her, taking her to shows and games. He soon got a job at the girls' dormitory, working 100 hours a month chopping wood for stoves, cutting up beef and mopping up the kitchen. Despite the 25 cent per hour salary, Pauling was still having trouble managing his finances. He began eating one hot meal a day at a restaurant off campus to minimize his expenses. 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'd just finished taking himself. He worked forty hours a week in the laboratory and classroom and earned $100 a month. 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. 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.
In 1922, Pauling graduated from OAC 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 G. Dickinson. 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
Ph. D. in
physical chemistry and
mathematical physics,
summa cum laude, in 1925.
Personal life
During his senior year of college, Pauling taught a class called "Chemistry for Home Economic Majors". In one of those classes, he met
Ava Helen Miller from
Beavercreek, whom he married on
June 17,
1923. They had four children: Linus Carl Jr. (b. 1925); Peter Jeffress (1931-2003, a crystallographer and lecturer in chemistry); Edward Crellin (1937-1997, professor of biology at
San Francisco State University and the
University of California, Riverside), and Linda Helen, (b. 1932).
Pauling was raised as member of the
Lutheran Church and later joined the
Unitarian Universalist Church and declared publicly his
atheist belief.
Career
Pauling had first been exposed to the concepts of
quantum theory and
quantum mechanics while he was studying at
Oregon State University. He later traveled to Europe on a
Guggenheim Fellowship 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 working in the new field of quantum mechanics and other branches of physics. Pauling became interested in seeing how quantum mechanics might be applied in his chosen field of interest, the
electronic structure of
atoms and
molecules. In Europe, 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 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. 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.
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. However, their relationship soured when Pauling began to suspect that Oppenheimer was becoming too close to 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. Although she flatly refused, she reported the incident to Pauling. That, and her apparent nonchalance about the incident, disquieted him, and he immediately cut off his relationship with Oppenheimer, resulting in a coolness between them that would last their lives.
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'd 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 1930s he 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. 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 half a century after first publication.
Part of Pauling's work on the nature of the chemical bond led to his introduction of the concept of
orbital hybridization. While it's 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's 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.
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. 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. 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.
Structure of the atomic nucleus
On
September 16,
1952, Pauling opened a new research notebook with these words "
I have decided to attack the problem of the structure of nuclei." On
October 15,
1965, Pauling published his Close-Packed Spheron Model of the atomic nucleus in two well respected journals,
Science, and
Proc. Natl. Acad. Sci. For nearly three decades, until his death in 1994, Pauling published numerous papers on his spheron cluster model.
Few modern text books on nuclear physics discuss the Pauling Spheron Model of the Atomic Nucleus, yet it provides a unique perspective, well published in the leading journals of science, on how fundamental "clusters of nucleons" can form shell structure in agreement with recognized theory of quantum mechanics. Pauling was well versed in quantum mechanics; he co-authored one of the first textbooks on the subject,
Introduction to Quantum Mechanics with Applications to Chemistry. In a 2006 review of models of atomic nuclei, Norman D. Cook said of the Pauling Spheron Model:
"…the model leads to a rather common-sense molecular build-up of nuclei and has an internal logic that's hard to deny…however…nuclear theorists have not elaborated on the idea of nucleon spherons, and Pauling's model hasn't entered mainstream nuclear theory." The 1965 Pauling Spheron Model of the atomic nucleus hasn't been replaced by a better model, but has simply been ignored.
The Pauling spheron nucleon clusters include the
deuteron[NP],
helion [PNP], and
triton [NPN]. Even-even nuclei were described as being composed of clusters of
alpha particles, as has often been done for light nuclei. He made an effort to derive the shell structure of nuclei from the
Platonic solids rather than starting from an independent particle model as in the usual
shell model. It was sometimes said at that time that this work received more attention than it would have if it had been done by a less famous person, but more likely Pauling was taking a unique approach to understanding the relatively new discovery in the late 1940s of
Maria Goeppert-Mayer of structure within the nucleus. In an interview Pauling commented on his model:
Biological molecules
In the mid-1930s, Pauling decided to strike out into new areas of interest. Early in his career, he was uninterested in studying molecules of
biological importance. But as Caltech was developing a new strength in biology, and Pauling interacted with such great biologists as
Thomas Hunt Morgan,
Theodosius Dobzhanski,
Calvin Bridges, and
Alfred Sturtevant, he changed his mind and switched to the study of biomolecules. His first work in this area involved 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 planarity of the peptide bond, Pauling and colleagues correctly proposed the
alpha helix and
beta sheet as the primary structural motifs in protein
secondary structure. This work exemplified his ability to think unconventionally; central to the structure was the unorthodox assumption that one turn of the helix may well contain a non-
integral number of amino acid residues.
Pauling then suggested a helical structure for
deoxyribonucleic acid (DNA); however, 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. 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, Watson and Crick were allowed to make a molecular model of DNA using unpublished data from
Maurice Wilkins and
Rosalind Franklin at
King's College. Early in 1953
James D. Watson and
Francis Crick proposed a correct structure for the DNA double helix. One of the impediments facing Pauling in this work was that he didn't have access to the high quality X-ray diffraction photographs of DNA taken by
Rosalind Franklin, which Watson and Crick had seen. He planned to attend a conference in England, where he might have been shown the photos, but he couldn't do so because his passport was withheld in 1952 by the State Department, on suspicions that he'd Communist sympathies. This was at the start of the
McCarthy period in the United States.
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 Delbruck, 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 in the journal
Science the first proof of a human disease caused by an abnormal
protein. 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 patented an armor piercing shell and was awarded a Presidential Medal of Merit. In 1946, he joined the
Emergency Committee of Atomic Scientists, chaired by
Albert Einstein. 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. 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.
In 1958, Pauling began a petition drive in cooperation with biologist
Barry Commoner, who had studied radioactive
strontium-90 in the
baby teeth of children across
North America and concluded that above-ground nuclear testing posed public health risks in the form of
radioactive fallout. He also participated in a public debate with the atomic physicist
Edward Teller about the actual probability of fallout causing mutations. In 1958, Pauling and his wife presented the
United Nations with a petition signed by more than 11,000 scientists calling for an end to
nuclear-weapon testing. Public pressure 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." The Caltech Chemistry Department, wary of his political views, didn't even formally congratulate him. However, the Biology Department 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'd previously been a member of that organisation. He continued his peace activism in the following years co-founding the
International League of Humanists in 1974. He was also one of the signers of the
Dubrovnik-Philadelphia Statement.
Many of Pauling's critics, including scientists who appreciated the contributions that he'd made in chemistry, disagreed with his political positions and saw him as a naïve 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." An extraordinary 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.
Development of the electric car
In the late 1950s, Pauling became concerned with the problem of
air pollution—particularly with the growing
smog problem in
Los Angeles. At the time, most scientists believed that the smog was due to chemical plants and refineries, not gasoline engine exhaust. Pauling worked with Arie Haagen-Smit and others at Caltech to show that smog was a product of automobile pollution instead of factory pollution. Shortly after this discovery, Pauling began work to develop a practical and affordable
electric car. He joined forces with the engineers at the Eureka Williams company in the development of the
Henney Kilowatt—the first speed-controlled electric car. After researching the electrophysics underlying the initial Kilowatt propulsion system, Pauling determined that traditional
lead-acid batteries wouldn't provide the power necessary to give electric cars the performance necessary to rival traditional
gasoline powered cars. Pauling accurately predicted that the low top speed and the short range of the Henney Kilowatt would make them impractical and unpopular. Pauling insisted on making the car more practical before releasing it to the public, and recommended that the project be discontinued until the appropriate battery was available commercially. Unfortunately, the Eureka Williams Company insisted that production plans for the car proceed; as Pauling predicted, the model experienced dismal sales.
Molecular medicine and medical research
In 1941, at age 40, Pauling was diagnosed with a serious form of
Bright’s disease, a fatal renal disease. Experts believed then that Bright's disease was untreatable. With the help of
Dr. Thomas Addis at Stanford, Pauling was able to control the disease with Addis' then unusual, low protein, salt-free diet. Addis also prescribed vitamins and minerals for all his patients.
In 1951, Pauling gave a lecture entitled, "Molecular Medicine". 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. It wasn't until he read "
Niacin Therapy in Psychiatry" by Abram Hoffer in 1965 that he realized that vitamins might have important biochemical effects unrelated to their prevention of associated deficiency diseases. Pauling published a brief paper, "
Orthomolecular Psychiatry", in the journal Science in 1968 (PMID 5641253) 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 isn't generally practiced by conventional medical professionals and is strongly criticized by some.
Pauling's work on
vitamin C in his later years generated controversy and was originally regarded by some adversaries in the field of medicine as outright
quackery. He was first introduced to the concept of high-dose vitamin C by biochemist
Irwin Stone in 1966. After becoming convinced of its worth, Linus Pauling took 10 grams of vitamin C every day to prevent colds. Excited by the 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. Cameron and Pauling wrote many technical papers and a popular book, "Cancer and Vitamin C", that discussed their observations. Three prospective, randomized, placebo-controlled trials were conducted by Moertel et al. at the Mayo Clinic; all three failed to prove a benefit for megadoses of vitamin C in cancer patients. Pauling denounced Charles Moertel's conclusions and handling of the final study as "fraud and deliberate misrepresentation." Pauling then published critiques of the second Mayo-Moertel cancer trial's flaws over several years as he was able to slowly unearth some of the trial's undisclosed details. However, the wave of adverse publicity generated by Moertel and the media effectively undercut Pauling's credibility and his vitamin C work for a generation, the oncological mainstream continued with other avenues of treatment. Always precariously perched since his molecular biologically inspired crusade to
stop atmospheric nuclear testing in the 1950s, the 1985 Mayo-Moertel confrontation left Pauling isolated from his institutional funding sources, academic support and a bemused public. He later collaborated with the Canadian physician
Abram Hoffer on a micronutrient regimen, including high-dose vitamin C, as adjunctive
cancer therapy.
As of 2006, new evidence of high-dose Vitamin C efficacy was proposed by a Canadian group of researchers. These researchers observed longer-than expected survival times in three patients treated with high doses of intravenous Vitamin C.
The researchers are reportedly planning a new
Phase I clinical trial.
The selective toxicity of vitamin C for cancer cells has been demonstrated
in-vitro (for example, in a
cell culture Petri dish), and was reported in 2005. The combination of case-report data and preclinical information suggest
biological plausibility and the possibility of clinical efficacy at the possible expense of critical toxicity at active doses; future clinical testing will ultimately determine the utility and safety of intravenous high-dose Vitamin C treatments for patients with cancer. Researchers released a paper demonstrating
in-vitro vitamin C killing of cancer cells in The Proceedings of the National Academy of Sciences in 2006.
With two colleagues, 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 of the employees that had previously worked at the Linus Pauling Institute in Palo Alto moved on to form the
Genetic Information Research Institute.
Pauling's legacy
Pauling died of
prostate cancer on
August 19,
1994, at 7:20 PM at home in
Big Sur, California. He was 93 years old. A gravemarker for him is in Oswego Pioneer Cemetery in
Lake Oswego, Oregon.
Pauling's contribution to science is held by many in the utmost regard. He 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 twentieth century on the list. Gautam R. Desiraju, the author of the Millennium Essay in Nature, claimed that Pauling was one of the greatest thinkers and visionaries of the millennium, along with Galileo, Newton, and Einstein. Pauling is also 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. Although his
valence bond approach fell short of accounting quantitatively for some of the characteristics of molecules, such as the
paramagnetic nature of
oxygen and the color of
organometallic complexes, and would later be superseded by the
Molecular Orbital Theory of
Robert Mulliken, the strength of Pauling's theory has lain in its simplicity, and it has endured. Nowadays the
Valence Bond theory still exists in its modern form and competes with the
Molecular Orbital Theory and
Density Functional Theory (DFT) for describing the chemical phenomena. Pauling's work on
crystal structure contributed significantly to the prediction and elucidation of the structures of complex minerals and compounds. His discovery of the
alpha helix and
beta sheet is a fundamental foundation for the study of
protein structure.
In his time, Pauling was frequently honored with the sobriquet "Father of
molecular biology", a contribution acknowledged by
Francis Crick. His discovery of
sickle cell anemia as a 'molecular disease' opened the way toward examining genetically acquired mutations at a molecular level.
Though the scientific community at large didn't agree with Pauling's conclusions in his vitamin-related medical research and writing, his entry into the fray gave a larger voice in the public mind to nutrients such as vitamins and minerals for disease prevention. Specifically, his protege Dr Mathias Rath, MD, continued his early works into Cellular Medicine, expanding the volumes of data about natural substances related in disease prevention and alleviation. Pauling's stand also led these subjects to be much more actively investigated by other researchers, including those at the Linus Pauling Institute which lists a dozen principal investigators and faculty who explore the role of micronutrients, plus phytochemicals, in health and disease.
Items named after Pauling include Linus Pauling Middle School in
Corvallis, Oregon, and
Pauling Field a small airfield located in
Condon, Oregon. Dr. Pauling spent his youth in Condon.
Linus Torvalds who develops the
Linux kernel is named after Pauling.
On 6 March 2008, the
United States Postal Service released a 41 cent stamp honoring Pauling.
Honors and awards
Pauling received numerous awards and honors during his career. Following are awards and honors he's received.
- 1931 Langmuir Prize, American Chemical Society
- 1941 Nichols Medal, New York Section, American Chemical Society
- 1947 Davy Medal, Royal Society
- 1948 United States Presidential Medal for Merit
- 1952 Pasteur Medal, Biochemical Society of France
- 1954 Nobel Prize in Chemistry
- 1955 Addis Medal, National Nephrosis Foundation
- 1955 Phillips Memorial Award, American College of Physicians
- 1956 Avogadro Medal, Italian Academy of b,la
- 1957 Paul Sabatier Medal
- 1957 Pierre Fermat Medal in Mathematics
- 1957 International Grotius Medal
- 1961 Humanist of the Year, American Humanist Association
- 1962 Nobel Peace Prize
- 1965 Republic of Italy
- 1965 Medal, Academy of the Rumanian People's Republic
- 1966 Linus Pauling Medal
- 1966 Silver Medal, Institute of France
- 1966 Supreme Peace Sponsor, World Fellowship of Religion
- 1972 United States National Medal of Science
- 1972 International Lenin Peace Prize
- 1977 Lomonosov Gold Medal, USSR Academy of Science
- 1979 Medal for Chemical Sciences, National Academy of Science
- 1984 Priestley Medal, American Chemical Society
- 1984 Award for Chemistry, Arthur M. Sackler Foundation
- 1987 Award in Chemical Education, American Chemical Society
- 1989 Vannevar Bush Award, National Science Board
- 1990 Richard C. Tolman Medal, Southern California, Section, American Chemical Society
Works by Linus Pauling
Pauling, L. The Nature of the Chemical Bond. Cornell University Press ISBN 0-8014-0333-2
Pauling, L., and Wilson, E. B. Introduction to Quantum Mechanics with Applications to Chemistry (Dover Publications) ISBN 0-486-64871-0
Pauling, L. Vitamin C, the Common Cold and the Flu (W.H. Freeman and Company) ISBN 0-7167-0360-2
Cameron E. and Pauling, L. 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 Books) ISBN 0-940159-21-X
Pauling, L. How to Live Longer and Feel Better (Avon Books) ISBN 0-380-70289-4
Pauling, L. Linus Pauling On Peace - A Scientist Speaks Out on Humanism and World Survival (Rising Star Press) ISBN 0-933670-03-6
Pauling, L. General Chemistry (Dover Publications) ISBN 0-486-65622-5
A Lifelong Quest for Peace with Daisaku Ikeda
Pauling, L. The Architecture of Molecules
Pauling, L. No More War!Further Information
Get more info on 'Linus Pauling'.
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