Glass Works: How Corning Created the Ultrathin, Ultrastrong
Material of the Future
Don
Stookey knew he
had botched the experiment. One day in 1952, the Corning Glass Works chemist
placed a sample of photosensitive glass inside a furnace and set the
temperature to 600 degrees Celsius. At some point during the run, a faulty
controller let the temperature climb to 900 degrees C. Expecting a melted blob
of glass and a ruined furnace, Stookey opened the door to discover that,
weirdly, his lithium silicate had transformed into a milky white plate. When he
tried to remove it, the sample slipped from the tongs and crashed to the floor.
Instead of shattering, it bounced.
The
future National Inventors Hall of Fame inductee didn’t know it, but he had just
invented the first synthetic glass-ceramic, a material Corning would later dub
Pyroceram. Lighter than aluminum, harder than high-carbon steel, and many times
stronger than regular soda-lime glass, Pyroceram eventually found its way into
everything from missile nose cones to chemistry labs. It could also be used in
microwave ovens, and in 1959 Pyroceram debuted as a line of space-age serving
dishes: Corningware.
The
material was a boon to Corning’s fortunes, and soon the company launched
Project Muscle, a massive R&D effort to explore other ways of strengthening
glass. A breakthrough came when company scientists tweaked a recently developed
method of reinforcing glass that involved dousing it in a bath of hot potassium
salt. They discovered that adding aluminum oxide to a given glass composition
before the dip would result in remarkable strength and durability. Scientists
were soon hurling fortified tumblers off their nine-story facility and
bombarding the glass, known internally as 0317, with frozen chickens. It could
be bent and twisted to an extraordinary degree before fracturing, and it could
withstand 100,000 pounds of pressure per square inch. (Normal glass can weather
about 7,000.) In 1962 Corning began marketing the glass as Chemcor and thought
it could work for products like phone booths, prison windows, and eyeglasses.
Yet
while there was plenty of initial interest, sales were slow. Some companies did
place small orders for products like safety eyeglasses. But these were recalled
for fear of the potentially explosive way the glass could break. Chemcor seemed
like it would make a good car windshield too, and while it did show up in a
handful of Javelins, made by American Motors, most manufacturers weren’t
convinced that paying more for the new muscle glass was worth it—especially
when the laminated stuff they’d been using since the ’30s seemed to work fine.
Corning
had invented an expensive upgrade nobody wanted. It didn’t help that crash
tests found that “head deceleration was significantly higher” on the
windshields—the Chemcor might remain intact, but human skulls would not.
After
pitches to Ford Motors and other automakers failed, Project Muscle was shut
down and Chemcor was shelved in 1971. It was a solution that would have to wait
for the right problem to arise.
The
office of Wendell Weeks, Corning’s CEO, is on the second floor, looking out
onto the Chemung River. It was here that Steve Jobs gave the 53-year-old Weeks
a seemingly impossible task: Make millions of square feet of ultrathin,
ultrastrong glass that didn’t yet exist. Oh, and do it in six months. The story
of their collaboration—including Jobs’ attempt to lecture Weeks on the
principles of glass and his insistence that such a feat could be
accomplished—is well known. How Corning actually pulled it off is not.
Weeks
joined Corning in 1983; before assuming the top post in 2005, he oversaw both
the company’s television and specialty glass businesses. Talk to him about
glass and he describes it as something exotic and beautiful—a material whose
potential is just starting to be unlocked by scientists. He’ll gush about its
inherent touchability and authenticity, only to segue into a lecture about
radio-frequency transparency. “There’s a sort of fundamental truth in the
design value of glass,” Weeks says, holding up a clear pebble of the stuff.
“It’s like a found object; it’s cool to the touch; it’s smooth but has surface
to it. What you’d really want is for this to come alive. That’d be a perfect
product.”
Weeks
and Jobs shared an appreciation for design. Both men obsessed over details. And
both gravitated toward big challenges and ideas. But while Jobs was dictatorial
in his management style, Weeks (like many of his predecessors at Corning) tends
to encourage a degree of insubordination. “The separation between myself and
any of the bench scientists is nonexistent,” he says. “We can work in these
small teams in a very relaxed way that’s still hyperintense.”
Indeed,
even though it’s a big company—29,000 employees and revenue of $7.9 billion in
2011—Corning still thinks and acts like a small one, something made easier by
its relatively remote location, an annual attrition rate that hovers around 1
percent, and a vast institutional memory. (Stookey, now 97, and other legends
still roam the halls and labs of Sullivan Park, Corning’s R&D facility.)
“We’re all lifers here,” Weeks says, smiling. “We’ve known each other for a
long time and succeeded and failed together a number of times.”
One
of the first conversations between Weeks and Jobs actually had nothing to do
with glass. Corning scientists were toying around with microprojection
technologies—specifically, better ways of using synthetic green lasers. The
thought was that people wouldn’t want to stare at tiny cell phone screens to
watch movies and TV shows, and projection seemed like a natural solution. But
when Weeks spoke to Jobs about it, Apple’s chief called the idea dumb. He did
mention he was working on something better, though—a device whose entire
surface was a display. It was called the iPhone.
Jobs
may have dismissed green lasers, but they represented the kind of innovation
for innovation’s sake that defines Corning. So strong is this reverence for
experimentation that the company regularly invests a healthy 10 percent of its
revenue in R&D. And that’s in good times and in bad. When the
telecom bubble burst in 2000 and cratering fiber-optic prices sent Corning’s
stock from $100 to $1.50 per share by 2002, its CEO at the time reassured
scientists that not only was Corning still about research but that R&D
would be the path back to prosperity.
“They’re
one of the very few technology-based firms that have been able to reinvent
themselves on a regular basis,” says Rebecca Henderson, a professor at Harvard
Business School who has studied Corning’s history of innovation. “That’s so
easy to say, and it is so hard to do.” Part of that success lies in the
company’s ability not only to develop new technologies but to figure out how to
make them on a massive scale. Still, even when Corning succeeds at both, it can
often take the manufacturer decades to find a suitable—and profitable
enough—market for its innovations. As Henderson notes, innovation at Corning is
largely about being willing and able to take failed ideas and apply them
elsewhere.
The
idea to dust off the Chemcor samples actually cropped up in 2005, before Apple
had even entered the picture. Motorola had recently released the Razr V3, a
flip phone that featured a glass screen in lieu of the typical high-impact
plastic. Corning formed a small group to examine whether an 0317-like glass
could be revived and applied to devices like cell phones and watches. The old
Chemcor samples were as thick as 4 millimeters. But maybe they could be made
thinner. After some market research, executives believed the company could even
earn a little money off this specialty product. The project was codenamed
Gorilla Glass.
By
the time the call from Jobs came in February 2007, these initial forays hadn’t
gotten very far. Apple was suddenly demanding massive amounts of a 1.3-mm,
chemically strengthened glass—something that had never been created, much less
manufactured, before. Could Chemcor, which had never been mass-produced, be
married to a process that would yield such scale? Could a glass tailored for
applications like car windshields be made ultrathin and still retain its
strength? Would the chemical strengthening process even work effectively on
such a glass? No one knew. So Weeks did what any CEO with a penchant for
risk-taking would do. He said yes.
For
a material
that’s so familiar as to be practically invisible, modern industrial glass is
formidably complex. Standard soda-lime glass works fine for bottles and
lightbulbs but is terrible for other applications, because it can shatter into
sharp pieces. Borosilicate glass like Pyrex may be great at resisting thermal
shock, but it takes a lot of energy to melt it. At the same time, there are
really only two ways to produce flat glass on a large scale, something called
fusion draw and the float glass process, in which molten glass is poured onto a
bed of molten tin. One challenge a glass company faces is matching a
composition, with all its desired traits, to the manufacturing process. It’s
one thing to devise a formula. It’s another to manufacture a product out of it.
Regardless
of composition, the main ingredient in almost all glass is silicon dioxide (aka
sand). Because it has such a high melting point (1,720 degrees C), other
chemicals, like sodium oxide, are used to lower the melting temperature of the
mixture, making it easier to work with and cheaper to produce. Many of these
chemicals also happen to imbue glass with specific properties, such as
resistance to x-rays, tolerance for high temperatures, or the ability to
refract light and disperse colors. Problems arise, though, when the composition
is changed; the slightest tweak can result in a drastically different material.
Throwing in a dense element like barium or lanthanum, for example, will
decrease the melting temperature, but you risk not getting a homogeneous
mixture. And maxing out the overall strength of a glass means you’re also
making that glass more likely to fracture violently when it does fail.
Glass is a material ruled by trade-offs. This is why compositions, particularly
those that are fine-tuned for a specific manufacturing process, are fiercely
guarded secrets.
One
of the pivotal steps in glassmaking is the cooling. In large-scale
manufacturing of standard glass, it’s essential for the material to cool
gradually and uniformly in order to minimize the internal stresses that would
otherwise make it easier to break. This is called annealing. The goal with
tempered glass, however, is to add stress between the inner and outer
layer of the material. This, paradoxically, can make the glass stronger: Heat a
sheet of glass until it softens, then rapidly cool, or quench, its outer
surfaces. This outside shell quickly contracts while the inside remains molten.
As the center of the glass cools, it tries to contract, pulling on the outer
shell. A zone of tension forms in the center, while the outer surfaces are even
more tightly compressed. Tempered glass will eventually break if you chip
through this toughened outer compressive layer into the zone of tension. But
even thermal tempering has its limits. The amount of strengthening you can
achieve is dependent on how much the glass contracts upon cooling, and most
compositions will shrink only modestly.
The
interplay between compression and tension is best demonstrated by something
called a Prince Rupert’s drop. Formed by dripping globs of molten glass into
ice water, the quickly cooled and compressed heads of these tadpole-shaped droplets
can withstand massive amounts of punishment, including repeated hammer blows.
The thin glass at the end of the tail is more vulnerable, however, and if you
break it the fracture will propagate through the drop at 2,000 miles per hour,
releasing the inner tension. Violently. In some cases, a Prince Rupert’s drop
can explode with such force that it will actually emit a flash of light.
Chemical
strengthening, the method of fortifying glass developed in the ’60s, creates a
compressive layer too, through something called ion exchange. Aluminosilicate
compositions like Gorilla Glass contain silicon dioxide, aluminum, magnesium,
and sodium. When the glass is dipped in a hot bath of molten potassium salt, it
heats up and expands. Both sodium and potassium are in the same column on the
periodic table of elements, which means they behave similarly. The heat from
the bath increases the migration of the sodium ions out of the glass, and the
similar potassium ions easily float in and take their place. But because
potassium ions are larger than sodium, they get packed into the space more
tightly. (Imagine taking a garage full of Fiat 500s and replacing most of them
with Chevy Suburbans.) As the glass cools, they get squeezed together in this
now-cramped space, and a layer of compressive stress on the surface of the
glass is formed. (Corning ensures an even ion exchange by regulating factors
like heat and time.)Compared with thermally strengthened glass, the “stuffing”
or “crowding” effect in chemically strengthened glass results in higher surface
compression (making it up to four times as strong), and it can be done to glass
of any thickness or shape.
By
the end of March,
Corning was closing in on its formula. But the company also needed to
manufacture it. Inventing a new manufacturing process was out of the question,
as that could take years. To meet Apple’s deadline, two of Corning’s
compositional scientists, Adam Ellison and Matt Dejneka, were tasked with
figuring out how to adapt and troubleshoot a process the company was already
using. They needed something capable of spitting out massive quantities of
thin, pristine glass in a matter of weeks.
There
was really only one choice: fusion draw. In this technique, molten glass is
poured from a tank into a trough called an isopipe. The glass overflows on each
side, then the two streams rejoin under the isopipe. It’s drawn down at a
prescribed rate by rollers to form a continuous sheet. The faster it’s drawn,
the thinner the glass.
Corning’s
one fusion-capable factory in the US is in Harrodsburg, Kentucky. In early
2007, that plant’s seven 15-foot-tall tanks were going full blast, each
churning out more than 1,000 pounds per hour of sold-out LCD glass for TV
panels. One tank could meet Apple’s initial request. But first the old Chemcor
compositions had to be reformulated. The glass not only needed to be 1.3 mm
now, it also had to have better visual characteristics than, say, a pane in a
telephone booth. Ellison and his team had six weeks to nail it. To be
compatible with the fusion process, the glass also needed to be extra stretchy,
like chewing gum, at a fairly low temperature. The problem was, anything you do
to increase a glass’s gooeyness also tends to make it substantially more
difficult to melt. By simultaneously altering seven individual parts of the
composition—including changing the levels of several oxides and adding one new
secret ingredient—the compositional scientists found they were able to ramp up
the viscosity while also producing a finely tuned glass capable of higher
compressive stress and faster ion exchange. The tank started in May 2007. By
June, it had produced enough Gorilla Glass to cover seven football fields.
In
just five years, Gorilla Glass has gone from a material to an aesthetic—a
seamless partition that separates our physical selves from the digital
incarnations we carry in our pockets. We touch the outer layer and our body
closes the circuit between an electrode beneath the screen and its neighbor,
transforming motion into data. It’s now featured on more than 750 products and
33 brands worldwide, including notebooks, tablets, smartphones, and TVs. If you
regularly touch, swipe, or caress a gadget, chances are you’ve interacted with
Gorilla.
Corning’s
revenue from the glass has skyrocketed, from $20 million in 2007 to $700
million in 2011. And there are other uses beyond touchscreens. At this year’s
London Design Festival, Eckersley O’Callaghan—the design firm responsible for
some of Apple’s most iconic stores—unveiled a serpentine-like glass sculpture
made entirely from Gorilla Glass. It may even end up on windshields again: The
company is in talks to install it in future sports car models.
Today,
two yellow robotic arms grab 5-foot-square panels of Gorilla Glass with special
residue-limiting suction cups and place them in wooden crates. From
Harrodsburg, these crates are trucked to Louisville and loaded on a westbound
train. Once they hit the coast, the sheets get loaded onto freight ships for
their eventual date at one of Corning’s “finisher” facilities in China, where
they get their molten potassium baths and are cut into touchable rectangles.
Of
course, for all its magical properties, a quick scan of the Internet will
reveal that Gorilla Glass does fail, sometimes spectacularly so. It breaks when
phones are dropped, it spiders if they bend, it cracks when they’re sat on.
Gorilla Glass is, after all, glass. Which is why a small team at Corning spends
a good portion of the day smashing the hell out of the stuff.
“We
call this a Norwegian hammer,” says Jaymin Amin, pulling a metal cylinder out
of a wooden box. The tool is usually wielded by aircraft engineers to test the
sturdiness of a plane’s aluminum fuselage. But Amin, who oversees all new glass
development in the Gorilla family, pulls back the spring-loaded impact hammer
and releases 2 joules of impact energy onto a 1-mm-thick piece of glass, enough
to put a big dent in a block of wood. Nothing happens.
The
success of Gorilla Glass presents some unique challenges for Corning. This is
the first time the company has faced the demands of such rapid iteration: Each
time a new version of the glass is released, the way it performs in the field
has to be monitored for reliability and robustness. To that end, Amin’s team
collects hundreds of shattered Gorilla Glass phones. “Almost all breakage,
whether it’s big or small, begins at one spot,” says senior research scientist
Kevin Reiman, pointing to a nearly invisible chip on an HTC Wildfire, one of a
handful of crunched phones on the table in front of him. Once you actually
locate that spot, you can start to measure the crack to get an idea of how the
tension was applied to the glass; if you can reproduce a break, you can study
how it propagated and attempt to prevent it, either compositionally or through
chemical strengthening.
Armed
with this information, the rest of the group jumps in to re-create that precise
kind of failure over and over. They use lever presses; drop testers with
granite, concrete, and asphalt surfaces; free gravity ball drops; and various
industrial-looking torture devices armed with an arsenal of diamond tips.
There’s even a high-speed camera capable of filming at 1 million frames per
second to study flexure and flaw propagation.
All
this destruction and controlled mayhem has paid off. Compared with the first
version of the glass, Gorilla Glass 2 is 20 percent stronger (a third version
is due out early next year). The Corning composition scientists have
accomplished this by pushing the compressive stress to its limit—they were
being conservative with the first version of Gorilla—while managing to avoid
the explosive breakage that can come with that increase. Still, glass is a
brittle material. And while brittle materials tend to be extremely strong under
compression, they’re also extremely weak under tension: If you bend them, they
can break. The key to Gorilla Glass is that the compression layer keeps cracks
from propagating through the material and catastrophically letting tension take
over. Drop a phone once and the screen may not fracture, but you may cause
enough damage (even a microscopic nick) to critically sap its subsequent
strength. The next drop, even if it isn’t as severe, may be fatal. It’s one of
the inevitable consequences of working with a material that is all about
trade-offs, all about trying to create a perfectly imperceptible material.
Back
at the Harrodsburg
plant, a man wearing a black Gorilla Glass T-shirt is guiding a 100-micron-thick
sheet of glass (about the thickness of aluminum foil) through a series of
rollers. The machine looks like a printing press, and appropriately, the glass
that comes off it bends and flexes like a giant glimmering sheet of transparent
paper. This remarkably thin, rollable material is called Willow. Unlike Gorilla
Glass, which is meant to be used as armor, Willow is more like a raincoat. It’s
durable and light, and it has a lot of potential. Corning imagines it will
facilitate flexible smartphone designs and uber-thin, roll-up OLED displays. An
energy company could also use Willow for flexible solar cells. Corning even
envisions ebooks with glass pages.
Eventually,
Willow will ship out on huge spools, like movie reels, each holding up to 500
feet of glass. That is, once someone places an order. For now, rolls of glass
sit on the Harrodsburg factory floor, a solution waiting for the right problem
to arise.
Bryan
Gardiner
http://www.wired.com/wiredscience/2012/09/ff-corning-gorilla-glass/all/
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