Helen Blair Barlett was an American geologist, best known for her contribution to the design of spark plug insulators. [1] She received her Bachelor of Science degree in 1927 in geology from Ohio Wesleyan University. Following up her degree in geology, she attended Ohio State University granting her a PhD degree in mineralogy in 1931.
Helen Barlett attended Ohio Wesleyan University and graduated with a Bachelor of Science degree in geology in 1927, at the age of 27. [1] Bartlett received an AC Spark Plug Division fellowship and went on to attend Ohio State University where she was a member of multiple prestigious honors societies including Phi Beta Kappa. She graduated in 1931 [1] with a PhD in Mineralogy in her early 30’s. During her education at Ohio State University, Barlett worked as a petrographer at AC Ceramic Laboratory, where she later worked as a Mineralogist-Geologist following the completion of her doctorate. [1]
Upon receiving her PhD, she joined the AC Ceramic Research Department as a mineralogist-geologist where she remained until her retirement in 1966. In 1955, Helen was promoted to Ceramic research specialist, and was again promoted to Ceramic research supervisor the following year in 1956. Following her extended work at AC Ceramic Research Department, Barlett was once again promoted to Ceramic research scientist in 1959 securing a top technical position, and becoming the first woman to reach this status within the General Motors organization. Further, Barlett pushed gender boundaries within the transportation industry, attending technical sessions where she was often the only female in attendance. [1] She was a member of the Mineralogical Society of America, as well as a fellow of the American Ceramic Society, being one of the few female members at the time. She was also a member of the American Chemical Society and the American Association for the Advancement of Science.
She took a leave from her position at General Motors Corporation to work on The Manhattan Project, later returnining [2] to General Motors and remained there until she retired in 1966. [3] She worked as a senior scientist at the Massachusetts Institute of Technology (MIT) for a special ceramics-related research project. For the MIT project, which was among many under the scope of the Manhattan Project, she developed a nonporous porcelain for the interior construction of the bomb. [4] Manhattan Project is the code name for America's secret project to build the world's first atomic bomb. [3]
Barlett was a geologist who was interested in spark plugs, and contributed greatly to the motor vehicle world. Beginning in the 1930s, Helen Barlett began to make monumental strides for women within the automotive industry, [5] being the first to invent insulating materials for spark plugs using alumina ceramics. [6] When spark plug insulators were first invented, they were made of porcelain (stacked layers of mica) [6] and molded on a potter's wheel, and thus, were prone to break easily. [7] As a result of the high heats created through the combustion reactions and ignition of fuels, the spark plug which resides in the combustion chamber of an automotive vehicle is bound to experience wear from the elements and constant and repetitive heat. It was discovered that leaded petrol left lead deposits on the initial mica insulators, which negatively impacted the efficiency of the vehicles engines when the spark plug and its insulator were left unmaintained. [6]
Noticing this inefficiency in the previous insulators, Dr. Barlett used her previous knowledge in mineralogy and petrology, as well as the knowledge gained through experience working for AC Spark Plug (General Motors), to introduce a ceramic spark plug insulator made of material which would last longer as a result of its higher heat resistance and would require less maintenance overall. [6] By encasing the spark plugs, she had made possible for them to become quite durable. Prior to the design changes, spark plugs would get covered in byproducts spewed by the engine and had to be manually cleaned every 70 to 150 kilometers for the vehicle to function effectively. Alumina insulator material allows plugs to handle high heat and voltage within the spark plug, enabling vehicles to operate in a more clean and, in turn, more efficient manner. [8] Her essential work on spark plugs improved the overall capabilities of motor vehicles. In fact, Helen’s patented alumina spark plug insulators are so effective and efficient that they are still used in many present day automotive vehicles. In fact, Helen’s patented alumina spark plug insulators are so effective and efficient that they are still used in many present day automotive vehicles. [6] She has been credited to have discovered that high alumina metals, containing approximately 0.35 percent lithium oxide precipitated zeta alumina, and over the course of her career, gained 7 patents in connection with her work (4 of which regarded the spark plug insulator). [6]
In one of her first publications (November 1931), she examined Silicate melts containing ZrO2 using an X‐ray and microscope to find the form of crystallization of the zirconium compounds under different conditions of temperature and composition. The effect of certain fluxes on these compounds was also examined. [9]
In another published study (July 1932), Barnett would describe the occurrences and properties of crystalline alumina in silicate melts. It is said that Corundum, or alpha-A2O3, would generally show a tendency to crystallize in two different forms. The forms being rhombohedron, or basal plates. The form is determined by the composition of the crystalline melts in which crystallization takes place. For example, high-alumina melts that contain little to no silica, the melt would crystallize into rhombohedron. The crystals are nearly equidimensional and are often rounded, rather them being well-developed forms. They are also characterized by inclusions which could be gaseous or glass. As the silica content of a series of melts becomes greater, the tendency for the alumina to crystallize in thin plates will become more marked. Plates will vary according to the type of condition the plates are in, more specifically, heating and cooling. Rapidly cooled melts may be microscopic in size, while large batches, which have been allowed to cool slowly, would measure an inch or more across. All cases have been observed that plates are not only single crystals, but are composed of thin lamellae. The thin lamellae are made up by the parallel grouping of basal plates shortened by a hexagonal prism and elongated parallel to two opposite faces of the prism. It would produce very fine striations on the smooth surface of the plate, which are more or less regularly interrupted by the completion of the prism form. [10]
In another publication (1933), Barnett and Schwartzwalder used alcohol and benzene to determine the effect of solubility of different grain sizes. When alcohol was used with the grains, it resulted in a thin mixture. However, this varied. After more testing, Bartlett and Schwartzwalder discovered that alkali was the reason behind the different results in alcohol mixtures due to the addition of hydrochloric acid. When Barlett tested benzene with the grains, it resulted in poor grinding action and it was not effective in finding the effect of solubility on different grain sizes. Barlett and Schwartzwalder conclude in the article that certain organic grinding media such as polar molecules (especially alcohol) can be used to solve the “agglomeration, caking, and scumming” [11] problems associated with partially water-soluble silicate frits. [11]
In a later publication (December 1934), she examined two bodies differing in composition by a small percentage of Li2O that were found to show marked differences in physical properties, especially in thermal expansion. Petrographic examinations were made of the electric‐furnace products used as the non-plastics and of the fired porcelain to determine what structural or mineralogical differences might be responsible for these variations. The properties of a feldspar body, tested under similar conditions, are given for comparative purposes. [12]
Helen Barlett conducted an experiment to determine the rate at which kyanite breaks down into mullite and glass, and later published an article on her findings (September 1940). A furnace containing a thermocouple was used and platinum wires were wrapped around fragments of kyanite which were suspended by the furnace. Once heated, the sample was taken out of the furnace and was observed with a microscope to figure out if the kyanite had broken down into mullite and glass. Many trials were performed until the rate of decomposition at a certain temperature was achieved. Helen Barlett discovered that the rate at which North Carolina kyanite of various grain sizes decomposes into mullite and glass is in the temperature range of 1350° to 1600 °C. She also discovered that the decomposition of kyanite into mullite and glass varies on the source, size of kyanite, and temperature. [13]
Outside of her professional work, Helen Barlett had an experimental and unconventional interest in golf, often practicing for the summer gold season in Michigan during her vacations. Helen was also a prominent member of Flint’s Zonta International for several years, and as a remarkable female scientist, she was very enthusiastic about the Flint Science Fair. She continued to contribute to the development of mineralogy even after her retirement in 1966, by teaching groups of young students at Campbell College in Buies Creek, North Carolina. Following the passing of Helen Barlett, Campbell College established a memorial, accepting donations in her honour. Further, in her honour a mobile oxygen unit was built for the Whispering Pines area. [1]
Helen Blair Barlett died on August 25, 1969, at the age of 67. [1] Following the death of Helen Barlett, Campbell College established a memorial, accepting donations in her honour. Further, in her honour a mobile oxygen unit was built for the Whispering Pines area. [1] Further, her memorial was published through The American Mineralogist (Vol. 56, March–April, 1971), and held by her colleague Karl Schwartzwalder, whom she filed several patents with, at 1151 Terr. Rd., Holly, Mich. 48442. It was discussed in the publication that she made large strides for the inclusion of women within her profession and that her respectable, pleasant and lovable presence will be remembered. [1]
Kaolinite ( KAY-ə-lə-nyte, -lih-; also called kaolin) is a clay mineral, with the chemical composition: Al2Si2O5(OH)4. It is a layered silicate mineral, with one tetrahedral sheet of silica (SiO4) linked through oxygen atoms to one octahedral sheet of alumina (AlO6).
Kyanite is a typically blue aluminosilicate mineral, found in aluminium-rich metamorphic pegmatites and sedimentary rock. It is the high pressure polymorph of andalusite and sillimanite, and the presence of kyanite in metamorphic rocks generally indicates metamorphism deep in the Earth's crust. Kyanite is also known as disthene or cyanite.
Silicon dioxide, also known as silica, is an oxide of silicon with the chemical formula SiO2, commonly found in nature as quartz. In many parts of the world, silica is the major constituent of sand. Silica is one of the most complex and abundant families of materials, existing as a compound of several minerals and as a synthetic product. Examples include fused quartz, fumed silica, opal, and aerogels. It is used in structural materials, microelectronics, and as components in the food and pharmaceutical industries. All forms are white or colorless, although impure samples can be colored.
Aluminium oxide (or aluminium(III) oxide) is a chemical compound of aluminium and oxygen with the chemical formula Al2O3. It is the most commonly occurring of several aluminium oxides, and specifically identified as aluminium oxide. It is commonly called alumina and may also be called aloxide, aloxite, or alundum in various forms and applications. It occurs naturally in its crystalline polymorphic phase α-Al2O3 as the mineral corundum, varieties of which form the precious gemstones ruby and sapphire. Al2O3 is used to produce aluminium metal, as an abrasive owing to its hardness, and as a refractory material owing to its high melting point.
A spark plug is a device for delivering electric current from an ignition system to the combustion chamber of a spark-ignition engine to ignite the compressed fuel/air mixture by an electric spark, while containing combustion pressure within the engine. A spark plug has a metal threaded shell, electrically isolated from a central electrode by a ceramic insulator. The central electrode, which may contain a resistor, is connected by a heavily insulated wire to the output terminal of an ignition coil or magneto. The spark plug's metal shell is screwed into the engine's cylinder head and thus electrically grounded. The central electrode protrudes through the porcelain insulator into the combustion chamber, forming one or more spark gaps between the inner end of the central electrode and usually one or more protuberances or structures attached to the inner end of the threaded shell and designated the side, earth, or ground electrode(s).
Many ceramic materials, both glassy and crystalline, have found use as optically transparent materials in various forms from bulk solid-state components to high surface area forms such as thin films, coatings, and fibers. Such devices have found widespread use for various applications in the electro-optical field including: optical fibers for guided lightwave transmission, optical switches, laser amplifiers and lenses, hosts for solid-state lasers and optical window materials for gas lasers, and infrared (IR) heat seeking devices for missile guidance systems and IR night vision. In commercial and general knowledge domains, it is commonly accepted that transparent ceramics or ceramic glass are varieties of strengthened glass, such as those used for the screen glass on an iPhone.
A ferrite is one of a family of iron oxide-containing magnetic ceramic materials. They are ferrimagnetic, meaning they are attracted by magnetic fields and can be magnetized to become permanent magnets. Unlike many ferromagnetic materials, most ferrites are not electrically conductive, making them useful in applications like magnetic cores for transformers to suppress eddy currents.
Barium ferrite, abbreviated BaFe, BaM, is the chemical compound with the formula BaFe
12O
19. This and related ferrite materials are components in magnetic stripe cards and loudspeaker magnets.
Armstrong World Industries, Inc. is a Pennsylvania corporation incorporated in 1891. It is an international designer and manufacturer of wall and ceiling building materials. Based in Lancaster, Pennsylvania, AWI has a global manufacturing network of 26 facilities, including nine plants dedicated to its WAVE joint venture. In 2011, Armstrong's net sales were $2.86 billion, with operating income of $239.2 million.
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Mullite or porcelainite is a rare silicate mineral formed during contact metamorphism of clay minerals. It can form two stoichiometric forms: 3Al2O32SiO2 or 2Al2O3 SiO2. Unusually, mullite has no charge-balancing cations present. As a result, there are three different aluminium sites: two distorted tetrahedral and one octahedral.
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Dodecacalcium hepta-aluminate (12CaO·7Al2O3, Ca12Al14O33 or C12A7) is an inorganic solid that occurs rarely in nature as the mineral mayenite. It is an important phase in calcium aluminate cements and is an intermediate in the manufacture of Portland cement. Its composition and properties have been the subject of much debate, because of variations in composition that can arise during its high-temperature formation.
This is a list of pottery and ceramic terms.
A geopolymer is a vague pseudo-chemical term used to describe inorganic, typically bulk ceramic-like material that forms covalently bonded, non-crystalline (amorphous) networks, often intermingled with other phases. Many geopolymers may also be classified as alkali-activated cements or acid-activated binders. They are mainly produced by a chemical reaction between a chemically reactive aluminosilicate powder e.g. metakaolin or other clay-derived powders, natural pozzolan, or suitable glasses, and an aqueous solution that causes this powder to react and re-form into a solid monolith. The most common pathway to produce geopolymers is by the reaction of metakaolin with sodium silicate, which is an alkaline solution, but other processes are also possible.
CoorsTek, Inc. is a privately owned manufacturer of technical ceramics for aerospace, automotive, chemical, electronics, medical, metallurgical, oil and gas, semiconductor and many other industries. CoorsTek headquarters and primary factories are located in Golden, Colorado, US. The company is wholly owned by Keystone Holdings LLC, a trust of the Coors family. John K. Coors, a great-grandson of founder and brewing magnate Adolph Coors Sr., and the fifth and youngest son of longtime chairman and president Joseph Coors, retired as president and chairman in January 2020 after 22 years at the helm.
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