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#1 Science HQ » Nobelium » Yesterday 18:21:57
- Jai Ganesh
- Replies: 0
Nobelium
Gist
Nobelium (No) is a synthetic, radioactive chemical element with atomic number 102, named after Alfred Nobel. It is a transuranic element in the actinide series and has no uses beyond scientific research due to its high instability and short half-life. Nobelium is produced in laboratories through nuclear reactions, such as the bombardment of californium with carbon-12 ions.
Nobelium has no practical applications outside of fundamental scientific research due to its extreme instability and the minuscule quantities in which it can be produced. Scientists use it to study the properties of super-heavy elements, test the limits of the periodic table, and validate theoretical models of atomic structure and the actinide series.
Summary
Nobelium is a synthetic chemical element; it has symbol No and atomic number 102. It is named after Alfred Nobel, the inventor of dynamite and benefactor of science. A radioactive metal, it is the tenth transuranium element, the second transfermium, and is the fourteenth member of the actinide series. Like all elements with atomic number over 100, nobelium can only be produced in particle accelerators by bombarding lighter elements with charged particles. A total of twelve nobelium isotopes are known to exist; the most stable is 259No with a half-life of 58 minutes, but the shorter-lived 255No (half-life 3.1 minutes) is most commonly used in chemistry because it can be produced on a larger scale.
Chemistry experiments have confirmed that nobelium behaves as a heavier homolog to ytterbium in the periodic table. The chemical properties of nobelium are not completely known: they are mostly only known in aqueous solution. Before nobelium's discovery, it was predicted that it would show a stable +2 oxidation state as well as the +3 state characteristic of the other actinides; these predictions were later confirmed, as the +2 state is much more stable than the +3 state in aqueous solution and it is difficult to keep nobelium in the +3 state.
In the 1950s and 1960s, many claims of the discovery of nobelium were made from laboratories in Sweden, the Soviet Union, and the United States. Although the Swedish scientists soon retracted their claims, the priority of the discovery and therefore the naming of the element was disputed between Soviet and American scientists. It was not until 1992 that the International Union of Pure and Applied Chemistry (IUPAC) credited the Soviet team with the discovery. Even so, nobelium, the Swedish proposal, was retained as the name of the element due to its long-standing use in the literature.
Details
Nobelium (No) is a synthetic chemical element of the actinoid series of the periodic table, atomic number 102. The element was named after Swedish chemist Alfred Nobel.
Not occurring in nature, nobelium was first claimed by an international team of scientists working at the Nobel Institute of Physics in Stockholm in 1957. They reported synthesis of an isotope of element 102 (either isotope 253 or 255) that decayed by emitting alpha particles with a half-life of about 10 minutes. They named it nobelium. In 1958 American chemists Albert Ghiorso, T. Sikkeland, J.R. Walton, and Glenn T. Seaborg at the University of California, Berkeley, reported the isotope 254 as a product of the bombardment of curium (atomic number 96) with carbon ions (atomic number 6) in a heavy-ion linear accelerator. In the same year, a Soviet scientific team led by Georgy Flerov at the Joint Institute for Nuclear Research in Dubna, Russia, achieved a similar result. Other experiments performed in the Soviet Union (at the I.V. Kurchatov Institute of Atomic Energy, Moscow, and at Dubna) and in the United States (Berkeley) failed to confirm the Stockholm discovery. Subsequent research in the following decade (primarily at Berkeley and Dubna) led the International Union of Pure and Applied Chemistry to conclude that Dubna papers published in 1966 established the existence of the isotope nobelium-254 with an alpha-decay half-life of about 51 seconds.
Of the isotopes of nobelium that have been produced, nobelium-259 (58-minute half-life) is the stablest. Using traces of this isotope, radiochemists have shown nobelium to exist in aqueous solution in both the +2 and +3 oxidation states. Cation-exchange chromatography and coprecipitation experiments showed conclusively that the +2 state is stabler than the +3 state, an effect more pronounced than was anticipated in comparison with the homologous lanthanoid element ytterbium (atomic number 70). Thus, No2+ is chemically somewhat similar to the alkaline-earth elements calcium, strontium, and barium. Nobelium metal has not been prepared, but its properties have been predicted to be similar to those of the alkaline-earth metals and europium.
Element Properties:
atomic number : 102
stablest isotope : 255
oxidation states : +2, +3.
Additional Information:
Appearance
Nobelium is a radioactive metal. Only a few atoms have ever been made. Its half-life is only 58 minutes.
Uses
Nobelium has no uses outside research.
Biological role
Nobelium has no known biological role. It is toxic due to its radioactivity.
Natural abundance
Nobelium is made by bombarding curium with carbon in a device called a cyclotron.
#2 Re: Dark Discussions at Cafe Infinity » crème de la crème » Yesterday 17:55:37
2364) Hannes Alfvén
Gist:
Work
The phenomenon of aurora borealis occurs when bursts of charged particles from the sun collide with the earth’s magnetic field. These jets of particles are an example of a special state of matter—plasma. Plasma is a gas comprised of electrons and ions (electrically charged atoms) that forms at high temperatures. From the late 1930s onward, Hannes Alfvén developed a theory about aurora borealis, which led to magneto-hydrodynamics; the theory of the relationships between a plasma’s movements, electric currents and fields, and magnetic fields.
Summary
Hannes Alfvén (born May 30, 1908, Norrköping, Sweden—died April 2, 1995, Djursholm) was an astrophysicist and winner, with Louis Néel of France, of the Nobel Prize for Physics in 1970 for his essential contributions in founding plasma physics—the study of plasmas (ionized gases).
Alfvén was educated at Uppsala University and in 1940 joined the staff of the Royal Institute of Technology, Stockholm. During the late 1930s and early ’40s he made remarkable contributions to space physics, including the theorem of frozen-in flux, according to which under certain conditions a plasma is bound to the magnetic lines of flux that pass through it. Alfvén later used the concept to explain the origin of cosmic rays.
In 1939 Alfvén published his theory of magnetic storms and auroral displays in the atmosphere, which immensely influenced the modern theory of the magnetosphere (the region of Earth’s magnetic field). He discovered a widely used mathematical approximation by which the complex spiral motion of a charged particle in a magnetic field can be easily calculated. Magnetohydrodynamics (MHD), the study of plasmas in magnetic fields, was largely pioneered by Alfvén, and his work has been acknowledged as fundamental to attempts to control nuclear fusion.
After numerous disagreements with the Swedish government, Alfvén obtained a position (1967) with the University of California, San Diego. Later he divided his teaching time between the Royal Institute of Technology in Stockholm and the University of California.
Alfvén devised “plasma cosmology,” a concept that challenged the big-bang model of the origin of the universe. The theory posited that the universe had no beginning (and has no foreseeable end) and that plasma—with its electric and magnetic forces—has done more to organize matter in the universe into star systems and other large observed structures than has the force of gravity. Much of Alfvén’s early research was included in his Cosmical Electrodynamics (1950). He also wrote On the Origin of the Solar System (1954), Worlds-Antiworlds (1966), and Cosmic Plasma (1981).
Details
Hannes Olof Gösta Alfvén (30 May 1908 – 2 April 1995) was a Swedish electrical engineer, plasma physicist and winner of the 1970 Nobel Prize in Physics for his work on magnetohydrodynamics (MHD). He described the class of MHD waves now known as Alfvén waves. He was originally trained as an electrical power engineer and later moved to research and teaching in the fields of plasma physics and electrical engineering. Alfvén made many contributions to plasma physics, including theories describing the behavior of aurorae, the Van Allen radiation belts, the effect of magnetic storms on the Earth's magnetic field, the terrestrial magnetosphere, and the dynamics of plasmas in the Milky Way galaxy.
Education
Alfvén received his PhD from the University of Uppsala in 1934. His thesis was titled "Investigations of High-frequency Electromagnetic Waves."
Early years
In 1934, Alfvén taught physics at both the University of Uppsala and the Nobel Institute for Physics (later renamed the Manne Siegbahn Institute of Physics) in Stockholm, Sweden. In 1940, he became professor of electromagnetic theory and electrical measurements at the Royal Institute of Technology in Stockholm. In 1945, he acquired the nonappointive position of Chair of Electronics. His title was changed to Chair of Plasma Physics in 1963. From 1954 to 1955, Alfvén was a Fulbright Scholar at the University of Maryland, College Park. In 1967, after leaving Sweden and spending time in the Soviet Union, he moved to the United States. Alfvén worked in the departments of electrical engineering at both the University of California, San Diego and the University of Southern California.
Later years
In 1991, Alfvén retired as professor of electrical engineering at the University of California, San Diego and professor of plasma physics at the Royal Institute of Technology in Stockholm.
Alfvén spent his later adult life alternating between California and Sweden. He died at the age of 86.
Personal life
Alfvén was married for 67 years to his wife Kerstin (1910–1992). They raised five children, one boy and four girls. Their son became a physician, while one daughter became a writer and another a lawyer in Sweden. The writer was Inger Alfvén and is well known for her work in Sweden. The composer Hugo Alfvén was Hannes Alfvén's uncle.
Alfvén studied the history of science, oriental philosophy, and religion. On his religious views, Alfven was irreligious and critical of religion. He spoke Swedish, English, German, French, and Russian, and some Spanish and Chinese. He expressed great concern about the difficulties of permanent high-level radioactive waste management." Alfvén was also interested in problems in cosmology and all aspects of auroral physics, and used Schröder's well known book on aurora, Das Phänomen des Polarlichts. Letters of Alfvén, Treder, and Schröder were published on the occasion of Treder's 70th birthday. The relationships between Hans-Jürgen Treder, Hannes Alfvén and Wilfried Schröder were discussed in detail by Schröder in his publications.
Alfvén died on 2 April, 1995 at Djursholm aged 86.
#3 Re: This is Cool » Miscellany » Yesterday 17:25:20
2416) Calcium Carbonate
Gist
Calcium carbonate (CaCO3) is a common inorganic compound found naturally in rocks such as limestone, marble, and chalk, and is a major component of sea animal shells and eggshells. It is a white, odorless powder that is practically insoluble in water but dissolves readily in acid.
Calcium carbonate (CaCO3) is a substance widely used for various purposes, for example, as a filler and pigment material not only in paper, plastics, rubbers, paints, and inks but also in pharmaceutics, cosmetics, construction materials, and asphalts and as a nutritional supplement in animal foods.
Summary
Calcium carbonate is a chemical compound with the chemical formula CaCO3. It is a common substance found in rocks as the minerals calcite and aragonite, most notably in chalk and limestone, eggshells, gastropod shells, shellfish skeletons and pearls. Materials containing much calcium carbonate or resembling it are described as calcareous. Calcium carbonate is the active ingredient in agricultural lime and is produced when calcium ions in hard water react with carbonate ions to form limescale. It has medical use as a calcium supplement or as an antacid, but excessive consumption can be hazardous and cause hypercalcemia and digestive issues.
Preparation
The vast majority of calcium carbonate used in industry is extracted by mining or quarrying. Pure calcium carbonate (such as for food or pharmaceutical use), can be produced from a pure quarried source (usually marble).
Alternatively, calcium carbonate is prepared from calcium oxide. Water is added to give calcium hydroxide then carbon dioxide is passed through this solution to precipitate the desired calcium carbonate, referred to in the industry as precipitated calcium carbonate (PCC).
In a laboratory, calcium carbonate can easily be crystallized from calcium chloride (CaCl2), by placing an aqueous solution of CaCl2 in a desiccator alongside ammonium carbonate [NH4]2CO3. In the desiccator, ammonium carbonate is exposed to air and decomposes into ammonia, carbon dioxide, and water. The carbon dioxide then diffuses into the aqueous solution of calcium chloride, reacts with the calcium ions and the water, and forms calcium carbonate.
Details
Calcium carbonate (CaCO3) is a chemical compound consisting of one atom of calcium, one of carbon, and three of oxygen that is the major constituent of limestone, marble, chalk, eggshells, bivalve shells, and corals. Calcium carbonate is either a white powder or a colorless crystal. When heated, it produces carbon dioxide and calcium oxide (also called quicklime). Calcium carbonate has a molecular weight of 100.1 grams per mole.
Calcium carbonate occurs naturally in three mineral forms: calcite, aragonite, and vaterite. Calcite, the most common form, is known for the beautiful development and great variety of its crystals. A large percentage of calcite occurs in limestones, and calcite is also the chief component of marls, travertines, calcite veins, most cave deposits, many marbles and carbonatites, and some ore-bearing veins. Calcite is the stable form of calcium carbonate at most temperatures and pressures. Aragonite is the orthorhombic (i.e., having three unequal crystalline axes at right angles to one another) form of calcium carbonate. Though frequently deposited in nature, it is metastable at room temperature and pressure and readily inverts to calcite. Vaterite, the hexagonal form of calcium carbonate, is extremely rare and transforms into calcite or aragonite or both.
Calcium carbonate has many uses. Since ancient times, limestone has been burned to quicklime (CaO), slaked to hydrated lime [Ca(OH)2], and mixed with sand to make mortar. Limestone is one of the ingredients used in the manufacture of portland cement and is often employed as a flux in metallurgical processes, such as the smelting of iron ores. Crushed limestone is used widely as riprap, as aggregate for both concrete and asphalt mixes, as agricultural lime, and as an inert ingredient of medicines.
As marble, calcium carbonate is used for statuary and carvings and is a popular facing stone as polished slabs. The term marble is used differently in the marketplace from the way it is used in geology: in the marketplace, it is applied to any coarse-grained carbonate rock that will take a good polish rather than to metamorphic carbonate-rich rocks exclusively. Some coarsely crystalline diagenetic limestones are among the most widely used commercial “marbles.” Travertine and onyx marble (banded calcite) are also popular facing stones, usually for interior use.
Calcium carbonate obtained from its natural sources is used as a filler in a variety of products, such as paper, ceramics, glass, plastics, and paint. Synthetic calcium carbonate, called “precipitated” calcium carbonate, is employed when high purity is required, as in medicine (antacids and dietary calcium supplements), in food (baking powder), and for laboratory purposes.
Additional Information
Calcium carbonate is an ionic compound used as a calcium supplement or antacid used for the symptomatic relief of heartburn, acid indigestion, and sour stomach.
Calcium carbonate is an inorganic salt used as an antacid. It is a basic compound that acts by neutralizing hydrochloric acid in gastric secretions. Subsequent increases in pH may inhibit the action of pepsin. An increase in bicarbonate ions and prostaglandins may also confer cytoprotective effects. Calcium carbonate may also be used as a nutritional supplement or to treat hypocalcemia.
Calcium carbonate is a basic inorganic salt that acts by neutralizing hydrochloric acid in gastric secretions. It also inhibits the action of pepsin by increasing the pH and via adsorption. Cytoprotective effects may occur through increases in bicarbonate ion (HCO3-) and prostaglandins. Neutralization of hydrochloric acid results in the formation of calcium chloride, carbon dioxide and water. Approximately 90% of calcium chloride is converted to insoluble calcium salts (e.g. calcium carbonate and calcium phosphate).
#4 Dark Discussions at Cafe Infinity » Club Quotes - I » Yesterday 16:09:06
- Jai Ganesh
- Replies: 0
Club Quotes - 1
1. I win at golf. I'm a club champion many times at different clubs. I win at golf. I can sink the three-footer on the 18th hole when others can't. - Donald Trump
2. People have to understand one thing: at the age of 18, I arrived at a dream club like Manchester United. It was a dream come true. But, even at that moment, I was thinking about playing in England for some years and then going to play in Spain. Even at that time I was thinking that way, and I always gave 100% everything. - Cristiano Ronaldo
3. I wish someone had put a golf club in my hands, not skates on my feet. It is a really great game for business. It's a great game for making connections. - Condoleezza Rice
4. I started gymnastics when I was six years old. I was at day care, and they took us on a field trip to a gym club, Bannon's Gymnastix in Houston, and that's how I got started. - Simone Biles
5. I've never stopped being Argentine, and I've never wanted to. I feel very proud of being Argentine, even though I left there. I've been clear about this since I was very young, and I never wanted to change. Barcelona is my home because both the club and the people here have given me everything, but I won't stop being Argentine. - Lionel Messi
6. I can remember getting rejected systematically by casting directors as a young kid. I felt like the biggest outsider there ever was; that I'd never belong in that club. - Leonardo DiCaprio
7. I must have made a good impression because a club official to us into his office and asked me if I would sign on for a year with a view to becoming a professional. - Harold Larwood
8. When I was eight and a half, my parents moved to a part of Queens where there was a club nearby. We joined, and if you believe in someone up above, I think I was meant to play tennis. - John McEnroe.
#5 Re: Jai Ganesh's Puzzles » General Quiz » Yesterday 15:48:19
Hi,
#10609. What does the term in Geography Cartography mean?
#10610. What does the term in Geography Cartogram mean?
#6 Re: Jai Ganesh's Puzzles » English language puzzles » Yesterday 15:18:58
Hi,
#5805. What does the noun controller mean?
#5806. What does the adjective compulsive mean?
#7 Re: Jai Ganesh's Puzzles » Doc, Doc! » Yesterday 14:50:08
Hi,
#2495. What does the medical term Dorsiflexion mean?
#8 Jokes » Autumn Jokes - I » Yesterday 14:40:39
- Jai Ganesh
- Replies: 0
Q What did the tree say to autumn?
A: Leaf me alone.
* * *
Q: What did one autumn leaf say to another?
A: I'm falling for you.
* * *
Q: Why did summer catch autumn?
A: Because autumn is fall.
* * *
Q: How do you fix a broken pumpkin?
A: With a pumpkin patch.
* * *
Q: Why are trees very forgiving?
A: Because in the Fall they "Let It Go" and in the Spring they "turn over a new leaf".
* * *
#9 Re: Jai Ganesh's Puzzles » 10 second questions » Yesterday 14:22:48
Hi,
#9763.
#10 Re: Jai Ganesh's Puzzles » Oral puzzles » Yesterday 13:57:03
Hi,
#6269.
#11 Re: Exercises » Compute the solution: » Yesterday 13:40:28
Hi,
2613.
#12 Re: Exercises » Compute the solution: » 2025-10-12 21:46:13
Hi,
2612.
#13 Re: Dark Discussions at Cafe Infinity » crème de la crème » 2025-10-12 17:56:28
2363) Earl Wilbur Sutherland Jr.
Gist:
Work
Signals between different parts of the body are conveyed by small electrical impulses and by chemical substances, hormones and signal substances. Communication also takes place between different cell parts. Earl Sutherland investigated how hormones, especially adrenaline, work. He showed how signals from one cell to another are conveyed by a messenger—the hormone—and how signals within the cell are then conveyed by another messenger. Around 1960 he showed how cyclic adenosine monophosphate (cAMP) serves as the secondary messenger within the cell.
Summary
Earl W. Sutherland, Jr. (born Nov. 19, 1915, Burlingame, Kan., U.S.—died March 9, 1974, Miami, Fla.) was an American pharmacologist and physiologist who was awarded the 1971 Nobel Prize for Physiology or Medicine for isolating cyclic adenosine monophosphate (cyclic AMP) and demonstrating its involvement in numerous metabolic processes that occur in animals.
Sutherland graduated from Washburn College (Topeka, Kansas) in 1937 and received his M.D. degree from Washington University Medical School (St. Louis, Missouri) in 1942. After serving in the U.S. Army during World War II, he joined the faculty of Washington University. In 1953 he became chairman of the department of pharmacology at Western Reserve University (now Case Western Reserve University) in Cleveland, Ohio, where in 1956 he discovered cyclic AMP. In 1963 Sutherland became a professor of physiology at Vanderbilt University (Nashville, Tennessee), and from 1973 until his death he was a member of the faculty of the University of Miami Medical School.
Details
Earl Wilbur Sutherland Jr. (November 19, 1915 – March 9, 1974) was an American pharmacologist and biochemist born in Burlingame, Kansas. Sutherland won a Nobel Prize in Physiology or Medicine in 1971 "for his discoveries concerning the mechanisms of the action of hormones", especially epinephrine, via second messengers, namely cyclic adenosine monophosphate, or cyclic AMP.
Early life and education
Sutherland was born on November 19, 1915, in Burlingame, Kansas. The second youngest of six children, he was raised by his mother, Edith M. Hartshorn, and his father, Earl W. Sutherland. Though his father, who was originally from Wisconsin, had attended Grinnell College for two years, he ultimately led an agrarian lifestyle that took him to both New Mexico and Oklahoma before settling down in Burlingame to raise a family. Edith, a Missouri native, had some training in nursing at what was called a "ladies college". To provide for the family, Sutherland's father ran a dry goods store, where he gave each of his children working jobs. Sutherland began fishing at the age of five, and this became a pastime that he enjoyed for most of his life.
As a high school student, Sutherland played and excelled in several sports, including tennis, basketball, and football.
In 1933, at the age of 17, Sutherland enrolled in Washburn College in Topeka, Kansas and began the pursuit of a Bachelor of Science degree. In order to pay for tuition, he worked throughout his undergraduate years as a medical staff assistant at a local hospital. Sutherland graduated in 1937, at the age of 21. He was then accepted to Washington University School of Medicine in St. Louis, where he developed a strong mentorship with Carl Ferdinand Cori. In 1942, Sutherland graduated with a Doctor of Medicine.
Career:
Academia and research
In 1940, while studying at the Washington University School of Medicine, Sutherland had his first encounter with research as an assistant in pharmacology in the laboratory of Carl Ferdinand Cori, who won a Nobel Prize in Physiology or Medicine in 1947 for his discovery of the mechanism of glycogen metabolism. Under Cori's guidance, Sutherland conducted research on the effects of the hormones epinephrine and glucagon on the breakdown of glycogen to glucose. In 1942, he worked as an intern at Barnes-Jewish Hospital in St. Louis.
After receiving his medical degree from Washington University in 1942, Sutherland served as a World War II army physician. He returned to Washington University in St. Louis in 1945, where he continued to do research in Cori's Laboratory. Sutherland accredits his decision to pursue a research career, as opposed to entering the medical profession, to his mentor Cori.
Sutherland held various teaching titles during his time at the Washington University School of Medicine, including instructor in pharmacology (1945–46), instructor in biochemistry (1946–50), assistant professor in biochemistry (1950–52), and associate professor in biochemistry (1952–53).
In 1953, Sutherland moved to Cleveland a position as a professor of pharmacology and chairman of the department of pharmacology at the school of medicine at Case Western Reserve University. There, he collaborated with Theodore W. Rall, also a professor of pharmacology, who was to become a lifelong research partner. Together, they conducted further research on the mechanism of hormone action at the molecular level. During his ten years at Case Western Reserve University, Sutherland made several ground-breaking discoveries that led to the identification of cyclic adenosine monophosphate, or cyclic AMP, and its role as a secondary messenger.
In 1963, Sutherland became professor of anatomy at Vanderbilt University School of Medicine in Nashville. His position allowed him to devote more time to his research. He continued his work on cyclic AMP, receiving financial support from the Career Investigatorship awarded to him by the American Heart Association in 1967. He held his teaching title at Vanderbilt University until 1973.
In 1973, after spending 10 years at Vanderbilt University, Sutherland moved to Miami, where he joined the faculty at Miller School of Medicine at the University of Miami as a distinguished professor of biochemistry. He continued to be involved in novel research about adenosine monophosphate and guanosine monophosphate, co-authoring four papers in 1973 alone.
Personal life
Sutherland married Mildred Rice in 1937, the same year that he graduated from Washburn College. In 1944, during World War II, Sutherland was called into service as a battalion surgeon under General George S. Patton, and was later sent to Germany, where he served as a staff physician in a military hospital until 1945. He had two sons and a daughter with Mildred Rice.
In 1962, Sutherland divorced his first wife. A year later, when he became professor of physiology at Vanderbilt University, Sutherland married Claudia Sebeste Smith, the assistant dean at the university, and they were together for the remainder of Sutherland's life.
#14 Re: This is Cool » Miscellany » 2025-10-12 16:47:58
2415) Poly tetrafluoro Ethylene
Gist
PTFE, or polytetrafluoroethylene, is a versatile synthetic fluoropolymer known for its non-stick, low-friction, and high-temperature resistant properties. Commonly recognized by the brand name Teflon, it is used in applications like non-stick cookware, electrical insulation for wires, and industrial parts such as bearings and pipe liners.
Polytetrafluoroethylene (PTFE) is used in various applications due to its nonstick, chemical-resistant, and low-friction properties, including cookware coatings (like Teflon), industrial components such as seals and gaskets, electrical insulation for wires, medical implants like grafts and catheters, and fabric treatments to provide water and stain resistance. Its ability to withstand extreme temperatures and harsh environments makes it a versatile material in many fields.
Summary
Polytetrafluoroethylene (PTFE) is a synthetic fluoropolymer of tetrafluoroethylene, and has numerous applications because it is chemically inert. The commonly known brand name of PTFE-based composition is Teflon by Chemours, a spin-off from DuPont, which originally invented the compound in 1938.
Polytetrafluoroethylene is a fluorocarbon solid, as it is a high-molecular-weight polymer consisting wholly of carbon and fluorine. PTFE is hydrophobic: neither water nor water-containing substances wet PTFE, as fluorocarbons exhibit only small London dispersion forces due to the low electric polarizability of fluorine. PTFE has one of the lowest coefficients of friction of any solid.
Polytetrafluoroethylene is used as a non-stick coating for pans and other cookware. It is non-reactive, partly because of the strength of carbon–fluorine bonds, so it is often used in containers and pipework for reactive and corrosive chemicals. When used as a lubricant, PTFE reduces friction, wear, and energy consumption of machinery. It is used as a graft material in surgery and as a coating on catheters.
PTFE and chemicals used in its production are some of the best-known and widely applied per- and polyfluoroalkyl substances (PFAS), which are persistent organic pollutants. PTFE occupies more than half of all fluoropolymer production, followed by polyvinylidene fluoride (PVDF).
For decades, DuPont used perfluorooctanoic acid (PFOA, or C8) during production of PTFE, later discontinuing its use due to legal actions over ecotoxicological and health effects of exposure to PFOA. DuPont's spin-off Chemours currently manufactures PTFE using an alternative chemical it calls GenX, another PFAS. Although GenX was designed to be less persistent in the environment compared to PFOA, its effects may be equally harmful or even more detrimental than those of the chemical it has replaced.
Details
Polytetrafluoroethylene (PTFE) is a a strong, tough, waxy, nonflammable synthetic resin produced by the polymerization of tetrafluoroethylene. Known by such trademarks as Teflon, Fluon, Hostaflon, and Polyflon, PTFE is distinguished by its slippery surface, high melting point, and resistance to attack by almost all chemicals. These properties have made it familiar to consumers as the coating on nonstick cookware; it is also fabricated into industrial products, including bearings, pipe liners, and parts for valves and pumps.
PTFE was discovered serendipitously in 1938 by Roy Plunkett, an American chemist for E.I. du Pont de Nemours & Company (now DuPont Company), who found that a tank of gaseous tetrafluoroethylene refrigerant had polymerized to a white powder. During World War II it was applied as a corrosion-resistant coating to protect metal equipment used in the handling of radioactive material for the Manhattan Project. For more than a decade after the war, PTFE saw little commercial use, owing to difficulties encountered in devising methods for processing the slippery, high-melting material. DuPont released its trademarked Teflon-coated nonstick cookware in 1960.
Tetrafluoroethylene (C2F4), a colourless, odourless gas, is made by heating chlorodifluoromethane (CHClF2) in the range of 600–700 °C (1,100–1,300 °F). Chlorodifluoromethane in turn is obtained by reacting hydrogen fluoride (HF) with chloroform (CHCl3). Tetrafluoroethylene monomers (small, single-unit molecules) are suspended or emulsified in water and then polymerized (linked into giant, multiple-unit molecules) under high pressure in the presence of free-radical initiators.
The fluorine atoms surround the carbon chain like a protective sheath, creating a chemically inert and relatively dense molecule with very strong carbon-fluorine bonds. The polymer is inert to most chemicals, does not melt below 327 °C (620 °F), and has the lowest coefficient of friction of any known solid. These properties allow it to be used for bushings and bearings that require no lubricant, as liners for equipment used in the storage and transportation of strong acids and organic solvents, as electrical insulation under high-temperature conditions, and in its familiar application as a cooking surface that does not require the use of fats or oils.
Fabrication of PTFE products is difficult because the material does not flow readily even above its melting point. Molded parts can be made by compressing and heating fine powders mixed with volatile lubricants. Metallic surfaces can be sprayed or dipped with aqueous dispersions of PTFE particles to form a permanent coating. Dispersions of PTFE can also be spun into fibres.
Additional Information
PTFE is used as an inner coating material in non-stick cookware. This unique polymer coating prevents food from sticking in the pans during the cooking process. Such cookware is also easy to wash. At normal cooking temperatures, PTFE-coated cookware releases various gases and chemicals that present mild to severe toxicity. Only few studies describe the toxicity of PTFE but without solid conclusions. The toxicity and fate of ingested PTFE coatings are also not understood. Moreover, the emerging, persistent, and well-known toxic environmental pollutant PFOA is also used in the synthesis of PTFA. There are some reports where PFOA was detected in the gas phase released from the cooking utensils under normal cooking temperatures. Due to toxicity concerns, PFOA has been replaced with other chemicals such as GenX, but these new alternatives are also suspected to have similar toxicity. Therefore, more extensive and systematic research efforts are required to respond the prevailing dogma about human exposure and toxic effects to PTFE, PFOA, and GenX and other alternatives.
#15 Dark Discussions at Cafe Infinity » Clowns Quotes and Clowning Quotes » 2025-10-12 15:57:03
- Jai Ganesh
- Replies: 0
Clowns and Clowning Quotes
1. I have this fear of clowns, so I think that if I surround myself with them, it will ward off all evil. - Johnny Depp
2. I realise that I do not change the course of history. I am an actor, I do a movie, that's the end of it. You have to realise we are just clowns for hire. After I had success it was great, at first, not to worry about money. It was on my mind when I was growing up. - Leonardo DiCaprio
3. Plus, you know, when I was young, there was a lot of respect for clowning in rock music - look at Little Richard. It was a part of the whole thing, and I always also believed that it released the audience. - Bruce Springsteen.
#16 Jokes » Photographer Jokes - III » 2025-10-12 15:40:10
- Jai Ganesh
- Replies: 0
Q: What does a pirate steal in his spare time?
A: Arrrrrrrrrrrrrrrrrt.
* * *
Q: Why was the photo arrested?
A: Because it was framed.
* * *
Q: What do you call someone hanging on a wall?
A: Art.
* * *
Q: Why can't you find good photography jokes?
A: They haven't been developed yet.
* * *
If a picture is worth a thousand words, then why shouldn't we judge a book by its cover?
* * *
#17 Re: Jai Ganesh's Puzzles » General Quiz » 2025-10-12 15:28:52
Hi,
#10607. What does the term in Biology Deoxyribonucleic acid (DNA) signify?
#10608. What does the term in Biology Depolarization mean?
#18 Re: Jai Ganesh's Puzzles » English language puzzles » 2025-10-12 15:01:43
Hi,
#5803. What does the adjective livid mean?
#5804. What does the noun llama mean?
#19 Re: Jai Ganesh's Puzzles » Doc, Doc! » 2025-10-12 14:49:56
Hi,
#2494. What does the medical term Bypass surgery mean?
#20 Re: Jai Ganesh's Puzzles » 10 second questions » 2025-10-12 14:41:13
Hi,
#9762.
#21 Re: Jai Ganesh's Puzzles » Oral puzzles » 2025-10-12 14:27:55
Hi,
#6268.
#22 Re: Exercises » Compute the solution: » 2025-10-12 14:11:19
Hi,
2611.
#23 Re: Dark Discussions at Cafe Infinity » crème de la crème » 2025-10-11 16:49:30
2362) Gerhard Herzberg
Gist:
Work
Our world consists of atoms that are assembled in molecules. During many chemical reactions, molecules are broken down into smaller parts, free radicals, that are quickly combined with other parts and form new molecules. Molecules absorb light of fixed wavelengths, and these light spectrums can be used with quantum mechanical calculations to figure out how different molecules are constructed. Gerhard Herzberg developed these methods, and during the 1950s and 1960s he mapped out the chemical structure of a great many free radicals.
Summary
Gerhard Herzberg (born Dec. 25, 1904, Hamburg, Ger.—died March 3, 1999, Ottawa, Ont., Can.) was a Canadian physicist and winner of the 1971 Nobel Prize for Chemistry for his work in determining the electronic structure and geometry of molecules, especially free radicals—groups of atoms that contain odd numbers of electrons. His work provided the foundation for molecular spectroscopy.
Herzberg became Privatdozent (unsalaried lecturer) at the Darmstadt Institute of Technology in 1930 but fled Nazi Germany in 1935 and obtained a position with the University of Saskatchewan. From 1945 to 1948 he worked at the University of Chicago’s Yerkes Observatory in Williams Bay, Wisconsin, after which he returned to Canada, where he joined the National Research Council, Ottawa.
Herzberg’s spectroscopic studies not only provided experimental results of prime importance to physical chemistry and quantum mechanics but also helped stimulate a resurgence of investigations into the chemical reactions of gases. He devoted much of his research to diatomic molecules, in particular the most common ones—hydrogen, oxygen, nitrogen, and carbon monoxide. He discovered the spectra of certain free radicals that are intermediate stages in numerous chemical reactions, and he was the first to identify the spectra of certain radicals in interstellar gas. Herzberg also contributed much spectrographic information on the atmospheres of the outer planets and the stars. His most important works are Atomspektren und Atomstruktur (1936; Atomic Spectra and Atomic Structure) and a long-standing reference work, the four-volume Molecular Spectra and Molecular Structure (1939–79).
Details
Gerhard Heinrich Friedrich Otto Julius Herzberg (December 25, 1904 – March 3, 1999) was a German-Canadian pioneering physicist and physical chemist, who won the Nobel Prize for Chemistry in 1971, "for his contributions to the knowledge of electronic structure and geometry of molecules, particularly free radicals". Herzberg's main work concerned atomic and molecular spectroscopy. He is well known for using these techniques that determine the structures of diatomic and polyatomic molecules, including free radicals which are difficult to investigate in any other way, and for the chemical analysis of astronomical objects. Herzberg served as Chancellor of Carleton University in Ottawa, Canada from 1973 to 1980.
Early life and family
Herzberg was born in Hamburg, Germany on December 25, 1904 to Albin H. Herzberg and Ella Biber. He had an older brother, Walter, who was born in January 1904. Herzberg started Vorschule (pre-school) late, after contracting measles. Gerhard and his family were atheists and kept this fact hidden. His father died in 1914, at 43 years of age, after having suffered from dropsy and complications due to an earlier heart condition. Herzberg graduated Vorschule shortly after his father's death. He married Luise Herzberg (née Oettinger), a spectroscopist and fellow researcher in 1929. (Luise Herzberg, died in 1971.)
Honours and awards
Herzberg's most significant award was the 1971 Nobel Prize in Chemistry, which he was awarded "for his contributions to the knowledge of electronic structure and geometry of molecules, particularly free radicals". During the presentation speech, it was noted that at the time of the award, Herzberg was "generally considered to be the world's foremost molecular spectroscopist."
Herzberg was honoured with memberships or fellowships by a very large number of scientific societies, received many awards and honorary degrees in different countries. The NSERC Gerhard Herzberg Canada Gold Medal for Science and Engineering, Canada's highest research award, was named in his honour in 2000. The Canadian Association of Physicists also has an annual award named in his honour. The Herzberg Institute of Astrophysics is named for him. He was made a member of the International Academy of Quantum Molecular Science. Asteroid 3316 Herzberg is named after him. In 1964 he was awarded the Frederic Ives Medal by the OSA. He was later named an Honorary Member of the Society. At Carleton University, there is a building named after him that belongs to the Physics and Mathematics/Statistics Departments, Herzberg Laboratories. Herzberg was elected a Fellow of the Royal Society (FRS) in 1951.
The main building of John Abbott College in Montreal is named after him. Carleton University named the Herzberg Laboratories building after him. A public park in the College Park neighbourhood of Saskatoon also bears his name.
#24 Re: This is Cool » Miscellany » 2025-10-11 16:29:31
2414) Benzaldehyde
Gist
Benzaldehyde (C6H5CHO) is the simplest aromatic aldehyde, known for its strong bitter almond-like odor. It is a colorless liquid used as a flavoring and fragrance agent, a solvent, and an intermediate in the production of dyes, pharmaceuticals, and other organic compounds. Benzaldehyde can be synthesized by oxidizing benzyl alcohol or through the hydrolysis of benzal chloride, and it has a melting point of -26 degrees Centigrade and a boiling point of 178.1 degrees Centigrade.
Benzaldehyde has numerous uses, most notably as a flavoring in foods to mimic almond, and as a fragrance in perfumes and other scented products. It is also a crucial intermediate in the synthesis of various organic compounds, including pharmaceuticals like ephedrine, as well as dyes, plastics, and other chemicals. Other applications include its use as a bee repellent and as a preservative in cosmetics and personal care products.
Summary
Benzaldehyde (C6H5CHO) is an organic compound consisting of a benzene ring with a formyl substituent. It is among the simplest aromatic aldehydes and one of the most industrially useful.
It is a colorless liquid with a characteristic odor similar to that of bitter almonds and cherry, and is commonly used in cherry-flavored sodas. A component of bitter almond oil, benzaldehyde can be extracted from a number of other natural sources. Synthetic benzaldehyde is the flavoring agent in imitation almond extract, which is used to flavor cakes and other baked goods.
Production
Benzaldehyde can be produced from both petroleum-based chemicals or plant-derived chemicals. Synthetic benzaldehyde is primarily produced using liquid phase chlorination and oxidation of toluene. Numerous other methods have been developed, such as the partial oxidation of benzyl alcohol, alkali hydrolysis of benzal chloride, and the carbonylation of benzene (the Gatterman-Koch reaction).
Natural benzaldehyde is produced from cinnamaldehyde obtained from cassia oil by the retro-aldol reaction: the cinnamaldehyde is heated in an aqueous/alcoholic solution between 90 °C and 150 °C with a base (most commonly sodium carbonate or bicarbonate) for 5 to 80 hours, followed by distillation of the formed benzaldehyde. This reaction also yields acetaldehyde. The natural status of benzaldehyde obtained in this way is controversial.
Occurrence
Benzaldehyde and similar chemicals occur naturally in many foods. Most of the benzaldehyde that people eat is from natural plant foods, such as almonds.
Almonds, apricot seeds, apple seeds, and cherry seed contain significant amounts of amygdalin. This glycoside breaks up under enzyme catalysis into benzaldehyde, hydrogen cyanide and two equivalents of glucose.
Details
Benzaldehyde (C6H5CHO) is the simplest representative of the aromatic aldehydes, occurring naturally as the glycoside amygdalin. Prepared synthetically, it is used chiefly in the manufacture of dyes, cinnamic acid, and other organic compounds, and to some extent in perfumes and flavouring agents.
Benzaldehyde was first isolated in 1803, and in the 1830s the German chemists Justus von Liebig and Friedrich Wöhler investigated the compound in studies that laid the foundation for the structural theory of organic chemistry. Industrially, benzaldehyde is made by a process in which toluene is treated with chlorine to form benzal chloride, followed by treatment of benzal chloride with water.
Benzaldehyde is readily oxidized to benzoic acid and is converted to addition products by hydrocyanic acid or sodium bisulfite. It undergoes simultaneous oxidation and reduction with alcoholic potassium hydroxide (a Cannizzaro reaction), giving potassium benzoate and benzyl alcohol; with alcoholic potassium cyanide, it is converted to benzoin; with anhydrous sodium acetate and acetic anhydride, it gives cinnamic acid.
Benzaldehyde is a colourless liquid with an odour of almond oil. It has a melting point of −26 °C (−14.8 °F) and a boiling point of 179 °C (354.2 °F). It is only slightly soluble in water and is completely soluble in ethanol and diethyl ether.
Additional Information
Benzaldehyde is an aromatic aldehyde in which the -CHO group is directly bonded to the aromatic ring. It is a compound with a molecular formula C7H6O that has several industrial applications, including the preparation of dyes, cosmetic products, and flavoring agents. It is also known as the oil of bitter almonds, as it is found in the glucoside amygdalin, which occurs in bitter almonds.
Benzoic acid, the simplest benzene-based carboxylic acid, has been known since the 16th century. One of its discoverers was the legendary clairvoyant Nostradamus. Its most common natural source is gum benzoin, a resin found in the bark of trees of the genus Styrax.
Most benzoic acid produced today is synthetic. Its first industrial synthesis was the hydrolysis of benzotrichloride to calcium benzoate, followed by acidification. This method has been completely displaced by the air oxidation of toluene, which avoids the problem of product contamination with chlorinated byproducts.
Many processed foods contain benzoic acid or one of its salts as a preservative. The acid inhibits the growth of bacteria, molds, and yeasts; it works best when the food has an acidic pH value. Benzoic acid also is often found in topical antifungal preparations.
#25 Re: Jai Ganesh's Puzzles » General Quiz » 2025-10-11 15:54:40
Hi,
#10605. What does the term in Biology Dendrite mean?
#10606. What does the term in Biology Denitrification mean?