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Biographie What’s glass, and how are modern-day researchers enhancing its properties?


You’d think we would know everything there is to know about decorative coloured glass by now. It’s been around for thousands of years, and it’s practically everywhere: in the walls of high-rise commercial buildings, in the windows of houses, in the windshields of automobiles and airplanes. Then there’s fine crystal, cookware, bottles, jars, and yes, chemical glassware—just to mention a few other products made of glass.






Still, just this year, researchers at Corning debunked a popular urban legend about glass. The legend states that glass is a supercooled liquid and points to stained glass windows in medieval cathedrals as evidence. Because glass flows slowly over time, the legend goes, some of those windows end up thicker at the bottom than at the top. That just ain’t so. The researchers used modeling and measurements and determined that stained glass of the type found in Westminster Abbey actually flows a maximum of about 1 nm over a billion years (J. Am. Ceram. Soc. 2017, DOI: 10.1111/jace.15092). The viscosity of glass—actually an amorphous solid—is too high for humans to observe its flow during their time on Earth. The thicker window edges may simply be an artifact of medieval glass processing.






Why glass is still capturing the minds of scientists and innovators depends on whom you ask. Arun K. Varshneya, president of Saxon Glass Technologies, which specializes in strengthening glass for the pharmaceutical and other industries, ticks off a long list of properties that make the stuff so useful. Beyond being transparent, it also stands up to wind, rain, snow, intense sunlight, and large swings in temperature, he says. It’s also chemically resistant and recyclable, and many varieties of glass are relatively inexpensive.






Richard K. Brow, a materials scientist at Missouri University of Science & Technology, says he finds glass captivating aesthetically. Some 40 years after delving into glass research, Brow remains fascinated with the way the molten material flows and forms an enormous variety of shapes, from microscopic spheres and fibers to large sheets and plates. “Glass is so useful,” he adds, because “the composition can be tuned broadly to tailor its properties and performance for such a wide range of applications.”






In addition to the common ones “in daily use by virtually all humanity,” some hot melt glass applications, such as fiber-optic cables for telecommunication and microscope and telescope lenses, “dramatically expand the frontiers of industry and science,” Robert Weisenburger Lipetz says. He’s the executive director of the Glass Manufacturing Industry Council, a nonprofit trade association. And glass isn’t just useful; it’s also big business. Lipetz says in the U.S. alone, glass manufacturing is estimated to be a $22.5 billion market.






People began using glass long before markets even existed. Early humans used obsidian—molten lava that cooled quickly—to make simple cutting tools and arrowheads. And although evidence from beads and other archaeological finds indicates that people figured out by 4,000 B.C.E. how to form glass coatings (glazes) by melting silica, the main component of sand, it would be another 2,500 years until ancient Mesopotamians got the hang of making hollow glass vessels, which they used for storing oils.










Around 200 B.C.E., Phoenicians developed the blowpipe and associated glass-blowing techniques, advances that historians say were the most important ones in the development of glass manufacturing. Those procedures enabled early glassmakers to shape molten glass into numerous useful and decorative products, which were easily transported and widely traded.






The main ingredients in glassmaking were widely available back then, and the recipe hasn’t changed much since that time. Sand—the source of silica (SiO2)—tops the list, typically coming in around 70% by weight. Other components include sodium carbonate (Na2CO3), which is known as soda ash, and limestone (CaCO3), which is plentiful in seashells.






Heating these materials together yields a molten mixture that cools to form a type of security wire glass known today as soda-lime glass. That’s the most common and least expensive type, accounting for roughly 90% of all manufactured glass.






Through trial and error, glassmakers learned to modify the composition of glass to tune its properties for various applications. Soda-lime glass, for example, does not tolerate high temperatures or sudden changes in temperature.






Adding a few percent of sodium borate to the melt incorporates boron oxide into the resulting glass. That material, a borosilicate glass, benefits from a lower coefficient of thermal expansion than soda-lime glass has, enabling the boron-containing form to withstand large and sudden temperature changes.






One particularly well-known borosilicate glass is Pyrex, the Corning family of heat-resistant bakeware, measuring cups, and other protective coating glass odds and ends for the kitchen. That line of commercial products, which recently celebrated its 100th anniversary, is also highly resistant to corrosive chemicals. The combination of heat resistance and resistance to damaging chemicals makes Pyrex flasks and pipelines well suited to laboratory and industrial use. Today’s Pyrex kitchen products are no longer made of borosilicate glass. Corning sold that division in 1998 and the new company switched to tempered soda-lime glass.






Lead glass is another variety of the familiar material that has been known for a long time. This form contains 20% or more lead oxide, boasts a high refractive index, and is relatively soft. Those properties make it sparkle, appear brilliant, and resist fracturing—all of which adds to the allure of fine goblets and other types of luxury lead glassware. Unfortunately, those beautiful goblets and decanters can pose health hazards due to lead leaching, according to the U.S. Food & Drug Administration.






Glass manufacturers have come up with many other glass formulations and continue to develop novel compositions and processing methods for custom applications. For example, Missouri-based Mo-Sci is developing a cottonlike bioactive borate glass for animal and human use that heals chronic skin ulcers and deep wounds. The nanofibrous material, which has antimicrobial properties, releases bioactive ions in the wound. The ions stimulate blood vessel growth and promote healing of soft and hard tissues.






Color blindness is another medical problem benefiting from a glass-based solution. Worldwide, millions of people are unable to distinguish various colors, especially reds from greens, under normal lighting conditions. Researchers at Enchroma designed stylish eyewear with custom-made lenses that filter select wavelengths from ambient light and help restore this component of vision to wearers who would otherwise be color-blind.






As useful as glass is, it would be even more useful if pieces of the material didn’t break easily. That shortcoming led Varshneya of Saxon Glass to develop an ion-exchange process to strengthen glass cartridges used in EpiPen epinephrine injectors, which are used for treating severe allergic reactions. The procedure replaces some of the sodium ions at the glass surface with larger potassium ions. The difference in ion size leads to compressive forces that toughen the surface by blocking the routes along which cracks could otherwise propagate. That treatment drastically reduced the number of EpiPen cartridges that broke during injection.






A related ion-exchange process lies at the heart of Corning’s Gorilla Glass, a chemically strengthened aluminosilicate material found in roughly 5 billion smartphones, tablets, and other portable electronic devices. Corning says a sheet of the newest version of the product less than 1 mm thick can survive 1.6-meter-high falls onto a rough surface 80% of the time. Manufacturers are now beginning to use the specialty glass for automobile windshields.






As industry scientists march forward in the development of new types of glass for tough portable electronics, data-dense computer hard drives, and high-capacity solid-state batteries, one thing’s for sure: Despite its advanced age, glass isn’t nearing retirement anytime soon.






To reach you, these words were encoded into signals of light moving about 125,000 miles per second through fiber-optic cables. These lines, splayed out across mountains and oceans, are made of hair-thin glass 30 times more transparent than the purest water. The technology was made possible in part by a team from Corning Incorporated. In 1970 they patented a type of cable that could transmit large amounts of information long distances, building on decades of work by other researchers.






Assuming you’re reading this on a smartphone, you also owe a debt to Steve Jobs, who in 2006 asked Corning to make a very thin, strong screen for his new product, the iPhone. The result, Gorilla Glass, now dominates the market for mobile devices: Phones made with the fifth generation of this product can be dropped onto a rough surface from a height of five feet (selfie height) and survive 80 percent of the time.






That’s just the start. Without glass, the world would be unrecognizable. It’s in the eyeglasses on your face, the lightbulbs in your room, and the windows that let you see outside. But despite its ubiquity, there’s still some debate within the research community about how to define “glass.” Some tend to emphasize its solid qualities, others its liquidity. Unanswered questions abound, like what makes one type of glass stronger than another, or why certain mixtures produce their unique optical or structural properties. Add to this the nearly infinite varieties of glass—one database lists over 350,000 types of currently known glass, though in principle the number of mixtures is limitless—and you get a surprisingly large and active field of research that regularly produces astounding new products. Glass has shaped the world more than any other substance, and in many sneaky ways, it’s the defining material of the human era.


“We’ve been making glass for thousands of years, and we still don’t have a good idea of what it is,” says Mathieu Bauchy, a ceramic printed glass expert and materials researcher at UCLA. Most glasses are made by heating and then quickly cooling a mixture of ingredients. In the case of flat glass, which makes up windows, that mixture may include sand (silicon dioxide), lime, and soda. Silicon provides the transparency, calcium provides the strength, and soda reduces the melting point. The swift cooling process doesn’t allow for atoms to form a regular pattern, explains Steve Martin, a glass scientist at Iowa State University.






That helps explain why glass is neither a crystalline solid nor a liquid, but rather an atomically disordered (or amorphous) solid. The atoms within want to reassume a crystal structure, but typically cannot because they are essentially frozen in place. You might have heard that cathedral windows flow over long periods of time, hence why some are thicker at the bottom. That’s false: Such windows were made that way, due to a manufacturing technique that involved spinning molten glass that created uneven patches. But glass does move; it just does so very slowly. A study published last year in the Journal of the American Ceramic Society estimated that room-temperature cathedral glass would take over 1 billion years to flow a single nanometer.






Though natural volcanic glasses like obsidian were fashioned into tools early in human history, glass was probably first manufactured in Mesopotamia more than 4,000 years ago. Likely, it was developed as an offshoot of ceramic-glaze production. The technique soon spread to ancient Egypt, and the first glass objects consisted of beads, amulets, and rods, often colored with added minerals to look like other materials, says Karol Wight, the executive director at the Corning Museum of Glass.






By early in the second millennium b.c., craftsmen began making small vessels like vases. Archaeologists have unearthed cuneiform tablets that spell out the recipe for such materials, but these were written in cryptic language meant to conceal trade secrets, Wight adds.






Glass had already become a serious business by the dawn of the Roman empire. The writer Petronius recounts the tale of a craftsman presenting Emperor Tiberius with a piece of allegedly unbreakable glass. Tiberius asked the craftsman, “Does anyone else know how to blow glass like this?” No, the craftsman replied, thinking he’d made it big. Without warning, Tiberius had the man beheaded. Although Tiberius’s motives remain mysterious, one can imagine such an invention would’ve disrupted Rome’s important glass industry, the first of its kind. 
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