Gorilla Glass Innovations, Alternatives, and the Future of Smart Glass Technology

Gorilla Glass has transformed the way we experience modern technology, striking the perfect balance between strength, clarity, and sleek aesthetics. Engineered by Corning, this chemically reinforced glass is a staple in smartphones, tablets, laptops, and even automotive displays.

Gorilla Glass offers a lightweight yet highly durable protective layer. As the demand for scratch resistant and impact resistant screens continues to rise, Gorilla Glass has become an indispensable feature in consumer electronics.

This glass technology is helping devices to endure daily wear and tear without compromising touch sensitivity or display quality.

In this article, we’ll take a closer look at the cutting edge technology behind Gorilla Glass. We will see widespread applications, and why it remains a game changer in today’s digital landscape.

Additionally, we’ll compare it with other alternatives like Dragontrail Glass, Sapphire Glass, and Panda Glass. We will evaluate their strengths and weaknesses to see how they stack up against Gorilla Glass.

What is Gorilla Glass?

Corning developed Gorilla Glass as a specially engineered glass with exceptional toughness, scratch resistance, and durability. It has become a go to material for smartphones, tablets, laptops, high end appliances, and even automotive displays.

Unlike conventional glass, Gorilla Glass undergoes an advanced ion exchange process. This significantly boosts its strength, making it more resistant to scratches and breakage.

How Gorilla Glass is Made?

A sophisticated and proprietary process known as ion exchange strengthening creates Gorilla Glass, the ultra tough and scratch resistant glass used in smartphones, tablets, and other electronic devices.

This unique manufacturing technique gives the glass its signature durability and resilience.

Raw Materials and Molten Glass Formation: Crafting the Foundation of Gorilla Glass

The process begins with a specially engineered glass composition called aluminosilicate glass a mix of silica (SiO₂), aluminum oxide (Al₂O₃), and other proprietary ingredients that enhance strength and durability.

Unlike regular glass, which primarily consists of silicon dioxide, Gorilla Glass contains precise amounts of aluminum oxide to improve toughness and optical clarity.

To transform these raw materials into glass, Corning heat them to extreme temperatures over 1,500°C (2,732°F) until they melt.

They then use a process called fusion draw to shape the molten glass into thin sheets. This ensures a uniform and ultra smooth surface without needing additional grinding or polishing.

At this stage, Corning pour the molten glass into a specialized container called an isopipe. This is a V-shaped trough that allows the glass to flow evenly over both sides.

This method results in a seamless sheet with consistent thickness and exceptional flatness. This is crucial for maintaining the strength and clarity of the final product.

ISOPIPE
In Corning's fusion glass manufacturing process, an isopipe is a V shaped trough that plays a crucial role in forming thin, uniform glass sheets. Molten glass is poured into the isopipe, where it overflows evenly over both sides, creating two thin streams that fuse at the bottom into a single, continuous sheet. This method ensures exceptional flatness and uniform thickness without the need for additional surface polishing.

What Makes Corning Fusion Draw Special?

Corning’s fusion draw process produces exceptionally thin glass with a pristine surface, making it ideal for touchscreens.

Because this technique ensures flawless dimensional stability, smartphone and tablet manufacturers widely use Gorilla Glass. This has contributed in Corning’s success in the industry.

Enhancing Durability: The Ion Exchange Process in Gorilla Glass

To enhance durability, the glass undergoes a strengthening process known as ion exchange. This involves submerging the glass in a hot potassium salt bath heated to approximately 400°C (752°F).

During this process, larger potassium ions (K⁺) replace the smaller sodium ions (Na⁺) within the glass surface.

Since potassium ions occupy more space, they create compressive stress, reinforcing the glass and making it more resistant to scratches and impacts.

As the glass cools, the embedded potassium ions lock into place, further enhancing its toughness. This controlled compression significantly boosts the gorilla glass hardness to withstand everyday wear and tear, ensuring greater durability for modern devices.

Precision Engineering: The Cutting and Finishing of Gorilla Glass

Once Corning complete the strengthening process, they carefully cut the glass to precise dimensions to fit specific applications. They then polish it to achieve a flawless, smooth finish.

To ensure the highest quality, they subject the glass to rigorous testing. This testing includes drop, scratch, and bend tests, verifying its clarity, strength, and durability before approving it for use.

Advanced Coatings and Applications: Enhancing Gorilla Glass for Everyday Use

After production, Gorilla Glass may receive additional treatments based on customer requirements.

These enhancements can include anti reflective coatings to reduce glare, anti smudge layers to resist fingerprints, or antimicrobial coatings to help prevent bacterial buildup.

Once finalized, the glass sheets are carefully packaged and shipped to manufacturers. These manufacturers seamlessly integrate glass sheets to devices such as smartphones, tablets, and laptops.

This entire unique process gives Gorilla Glass its signature durability and resistance to everyday wear and tear. In simple terms gorilla glass is much better than tempered glass.

If we compare aluminosilicate glass vs gorilla glass, former is much better with latest iteration like gorilla glass Victus, Armor, and latest gorilla glass ceramic.

Seamless Integration: How Gorilla Glass Becomes Part of Modern Devices

Corning works directly with manufacturers, supplying Gorilla Glass as part of the production process. Unlike a screen protector, consumers can’t simply purchase a sheet to apply to an existing device.

Instead, Corning functions as an original equipment manufacturer (OEM), meaning its glass is built into products from other brands.

While the final device may feature Corning’s durable glass, it is ultimately branded and sold by smartphone, tablet, and laptop manufacturers.

The Evolution of Chemically Strengthened Glass: From Corning’s Innovations to Gorilla Glass

Founded in 1851 and headquartered in Corning, New York, Corning Incorporated is a global leader in specialty glass, ceramics, and optical materials.

Corning laid the foundation for chemically strengthened glass in 1960 when it launched Project Muscle to develop stronger glass solutions.

A major breakthrough came in 1962, when Steven Kistler discovered that replacing smaller sodium ions with larger potassium ions significantly increased a glass’s compressive strength. The addition of aluminum and zirconium oxides further enhanced its durability.

By the late 1960s, Corning had developed Chemcor, an early commercial version of this glass. Various industries, including automotive and aviation, used it. It was notably incorporated into around 100 Dodge Dart and Plymouth Barracuda racing cars in 1968 to reduce weight.

First Generation Gorilla Glass

The modern revival of chemically strengthened glass began when Apple sought a stronger screen for the first iPhone. Steve Jobs, frustrated with scratches on a plastic prototype, turned to Corning for a solution.

The development of a durable, scratch resistant glass led to its debut with the first generation iPhone in 2007. Later, it was officially branded as Gorilla Glass in 2008.

Today, Corning is best known for Gorilla Glass, which has evolved through multiple generations. With each generation it has improved in strength, scratch resistance, and overall durability.

Beyond Gorilla Glass, Corning is a major player across multiple industries, contributing significantly to various technological advancements.

In display technologies, the company is known for its high quality LCD glass used in screens. Its expertise in optical communications has positioned it as a leader in fiber optics, facilitating faster and more efficient data transmission.

Additionally, Corning plays a crucial role in environmental technologies by producing ceramic filters that help control emissions. In the life sciences sector, the company is recognized for its laboratory glassware, which supports scientific research and innovation.

Major tech giants like Apple and Samsung continue to rely on Corning’s advanced glass solutions. This makes it a critical player in the tech and materials industry.

Corning’s Gorilla Glass: A Journey of Innovation and Durability

Corning’s Gorilla Glass has evolved significantly since its inception, continuously pushing the boundaries of durability and innovation. The journey began in 2007 with the original Gorilla Glass, making its debut on the first iPhone before officially launching in 2008.

By 2010, 200 million devices had adopted it. Gorilla Glass 2 arrived in 2012, prioritizing thinness and featuring on the Samsung Galaxy S III, quickly surpassing a billion devices.

In 2013, Gorilla Glass 3 introduced enhanced scratch resistance through atomic scale modeling, first appearing on the Samsung Galaxy S4.

Subsequent generations focused on specialized improvements Gorilla Glass 4 (2014) emphasized damage resistance. Gorilla Glass 5 (2016) enhanced drop protection, debuting on the Samsung Galaxy Note7.

That same year, Corning also introduced Gorilla Glass SR+, tailored for wearable devices.

Gorilla Glass 6 (2018) doubled its predecessor’s durability, and the DX and DX+ variants added antireflective properties, later adopted in smartphone cameras.

In 2019, Gorilla Glass 3+ provided improved durability for mid-range devices.

The 2020s marked major advancements, with Gorilla Glass Victus offering exceptional scratch resistance on the Samsung Galaxy Note 20 Ultra. In 2022, Victus 2 improved drop resilience on rough surfaces, seen in the Samsung Galaxy S23 series.

In 2024, Gorilla Armor set new standards with enhanced drop and scratch resistance and reduced reflections, making its debut on the Samsung Galaxy S24 Ultra, alongside Gorilla Glass 7i, designed for mid range smartphones.

The most recent Gorilla Glass versions are Gorilla Armor 2 (2025) and Gorilla Glass 7i (2024). Gorilla Armor 2 is designed for premium devices, while Gorilla Glass 7i focuses on mid-range and budget-friendly smartphones.

In March 2025, Corning unveiled Gorilla Glass Ceramic, a super-tough new material for phone screens! This new glass material is designed to significantly enhance smartphone screen durability. This Gorilla Glass Ceramic combines the benefits of glass and ceramic.

Corning created a hybrid material that can survive up to 10 drops onto asphalt. This makes it one of the toughest screen materials available at this time.

Gorilla Glass vs. Traditional Glass: What’s the Difference?

Feature	Gorilla Glass	Traditional Glass
Strength	Highly durable, impact-resistant	Easily breaks upon impact
Scratch Resistance	Resists minor scratches and scuffs	Prone to scratches
Thinness	Ultra-thin without compromising strength	Thicker but fragile
Clarity	High transparency and optical clarity	Can be less clear over time
Weight	Lightweight	Heavier

Gorilla Glass Durability: Rigorous Testing and Advanced Toughness

Gorilla Glass undergoes rigorous testing using methods like the Vickers hardness test, Knoop hardness test, drop tower test, and scratch tests.

Corning has continuously refined its glass to enhance durability and performance, with recent advancements demonstrating significant improvements.

New tests show that the latest versions, Victus 2 and Armor 2, are notably tougher.

Victus 2 withstands drops from 1 meter onto concrete and 2 meters onto asphalt.

Armor 2, featured in the Samsung Galaxy S25 Ultra, survives drops from 2.2 meters onto concrete.

In contrast, standard aluminosilicate glass shatters from a drop of just 0.8 meters.

Corning claims Gorilla Glass excels in both drop and scratch resistance.

Compared to standard strengthened aluminosilicate glass, Victus glass is twice as resistant to scratches. It also offers a 20% boost in durability at the same price as Gorilla Glass 6. Despite being only 0.4mm thick, it delivers superior protection.

In a Knoop diamond scratch test, ordinary aluminosilicate glass withstands 4 Newtons of force, while Gorilla Glass Victus handles up to 8 Newtons.

Gorilla Glass Victus 2 resists scratches four times better than similar glass. Gorilla Glass Armor 2 glass provides four times better scratch protection, even with anti-reflective coatings, keeping screens clearer for longer.

Modern smartphones are 15% heavier and feature screens that are 10% larger, so Gorilla Glass is built to endure this increased size and weight. Drop tests on rough surfaces like concrete and asphalt confirm its durability, making Victus 2 and Armor 2 essential for protecting today’s larger and more fragile smartphones.

Gorilla Glass in Modern Technology: From Smartphones to Smart Appliances

Most flagship smartphones from Apple, Samsung, and Google rely on Gorilla Glass for their displays, offering durability without compromising on sleekness and smoothness.

Beyond phones, premium laptops, smartwatches, and fitness trackers benefit from its lightweight yet highly durable nature.

In the automotive industry, modern car dashboards and infotainment systems use Gorilla Glass for scratch-resistant, highly responsive touchscreens.

Even high-end home appliances like refrigerators, ovens, and washing machines now feature Gorilla Glass control panels, combining style with superior scratch resistance.

Is Gorilla Glass Truly Scratch-Proof? Understanding Its Limitations

Gorilla Glass is designed to be highly scratch resistant, but that doesn’t mean it’s completely immune to scratches.

While everyday items like keys and coins typically won’t cause damage, materials like sand or other harder minerals can leave marks. To keep your screen in top shape, using a screen protector is always a smart choice.

Essential Tips for Caring for Gorilla Glass Screens

To keep Gorilla Glass screens in top condition, Corning advises following the device manufacturer’s cleaning instructions, avoiding harsh chemicals, and never submerging the device in cleaning agents.

Reliable sources on internet suggest using a microfiber cloth to wipe the screen and steering clear of sand or rough surfaces to prevent scratches.

For added protection, applying a tempered glass screen protector is a wise move. Personally, I’ve never used my phone without one. I also make sure to keep metal objects like keys and coins in a separate pocket from my phone to avoid accidental scratches.

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Alternatives of Gorilla Glass

For years, Gorilla Glass has set the standard for smartphone and tablet screens, but the market now offers several strong alternatives some even boasting better durability, scratch resistance, or affordability.

One notable competitor is Dragontrail Glass, developed by Asahi Glass Co. Device manufacturers recognize it for its impressive strength and ability to withstand drops, making it a solid choice.

Then there’s Sapphire Glass, a premium option often found in luxury watches and high end smartphones. While it’s on the pricier side, its exceptional scratch resistance makes it highly desirable.

Panda Glass, produced by China’s Tunghsu Optoelectronic, has been gaining traction in budget and mid-range devices. It delivers a good balance between durability and cost effectiveness, making it an attractive alternative.

Meanwhile, Ceramic Shield, Apple’s collaboration with Corning, takes screen toughness up a notch by infusing ceramic crystals into the glass, significantly boosting impact resistance.

Some brands are also experimenting with polycarbonate and hybrid glass plastic composites, which provide added flexibility and shatter resistance though they may trade off some scratch resistance in the process.

As technology continues to evolve, the push for tougher, more adaptable, and cost-efficient screen materials is driving innovation in the smartphone industry.

Dragontrail Glass: A Strong and Reliable Alternative to Gorilla Glass

Dragontrail Glass, developed by Asahi Glass Co. (AGC), is a high-strength, scratch resistant material designed for a wide range of devices, including smartphones, tablets, wearables, automotive displays, and industrial touch panels.

As a direct competitor to Corning’s Gorilla Glass, it offers impressive durability while maintaining a lightweight and slim profile.

Strengthened through an advanced ion exchange process, Dragontrail Glass is six times stronger than conventional soda lime glass.

This chemical reinforcement significantly enhances its scratch and impact resistance, making it an excellent choice for protecting electronic devices.

It can withstand contact with sharp objects like keys and coins, keeping screens pristine while also reducing the risk of shattering from accidental drops.

Despite its robustness, Dragontrail Glass remains slim and ergonomic, allowing manufacturers to design sleek and stylish devices.

Its high transparency and smooth touch responsiveness make it ideal for modern touchscreen displays. Additionally, it is environmentally friendly, as it contains no harmful substances like arsenic, lead, or antimony, aligning with global safety standards.

Both Dragontrail and Gorilla Glass prioritize durability through chemical strengthening, making them popular choices for electronic displays.

However, Dragontrail stands out for its balanced combination of strength, clarity, and cost effectiveness, making it a preferred option in markets like Japan, China, and India, where manufacturers seek a reliable yet economical solution.

Where Dragontrail Glass excels?

Dragontrail Glass plays a crucial role across industries, particularly in smartphones, tablets, and wearables that require superior scratch resistance and long lasting clarity.

It is also widely used in automotive touchscreen systems, where durability and responsiveness are essential.

Many manufacturers choose Dragontrail for its blend of durability, affordability, and design flexibility, enabling the creation of strong yet lightweight devices without compromising display quality.

As demand for high performance, durable glass continues to grow, Dragontrail Glass remains a standout choice. Its balance of strength, transparency, and environmental safety makes it an ideal solution for manufacturers and consumers alike.

With widespread adoption in electronics, automotive, and industrial applications, Dragontrail Glass plays a vital role in extending the lifespan and reliability of modern devices.

Sapphire Glass: The Ultimate Scratch-Resistant Material with Trade Offs

Sapphire glass is known for its excellent light transmission, making it a top choice for optical applications. It is highly resistant to harsh environments, maintaining its clarity and durability over time.

Sapphire glass, composed of crystallized aluminum oxide (Al₂O₃), is a synthetic material developed using techniques pioneered by Auguste Verneuil.

With a Mohs hardness rating of 9 second only to diamond, it offers superior scratch resistance compared to chemically strengthened glasses like Gorilla Glass or Dragontrail.

However, despite its impressive scratch resistance, sapphire glass is more susceptible to cracking or shattering upon impact.

Additionally, its high production cost limits its widespread use in consumer electronics. Another significant drawback is its weight sapphire glass is 67% heavier than Corning’s Gorilla Glass, making it over 1.5 times as dense.

While it excels in durability against scratches, the high manufacturing cost and impact fragility make sapphire glass a less practical option for mass-market devices.

In comparison between sapphire glass vs gorilla glass, as per the usage scenario of mobile devices gorilla glass has clear advantages.

The Rise of Panda Glass: A Budget-Friendly Alternative to Gorilla Glass

Panda Glass is an alkali aluminosilicate sheet glass that has been gaining attention as a budget friendly alternative to Gorilla Glass.

It strikes a balance between scratch resistance and high transparency, making it a solid choice for mid-range and budget devices that prioritize screen protection without driving up costs.

While Panda Glass offers reliable scratch resistance, its shatter resistance falls short compared to Gorilla Glass. This means it can withstand daily wear and tear but may be more prone to breaking if dropped onto hard surfaces.

However, one of its key advantages is its high transparency, ensuring that smartphone displays remain clear and vibrant.

Manufactured in China, Panda Glass is an increasingly competitive option in the growing market for durable yet cost effective screen protection. It provides good defense against scratches, helping screens endure everyday use with minimal wear.

Though not as well known as Corning’s Gorilla Glass, it serves as a viable option for devices that don’t require top-tier protection.

Like any glass material, Panda Glass remains susceptible to scratches and cracking if subjected to rough handling or sharp objects. Careful usage is recommended to extend its lifespan.

Despite this, it continues to gain traction in the mobile device market as an affordable yet durable screen protection solution.

How to Choose the Right Glass for Your Device: Gorilla vs. Dragontrail vs. Sapphire vs. Panda

Feature	Gorilla Glass	Dragontrail Glass	Sapphire Glass	Panda Glass
Scratch Resistance	Good	Moderate	Very High	Fair
Impact Resistance	High	Moderate	Low	Fair
Transparency	Good	Moderate	Excellent	Fair
Cost	Moderate	Affordable	Very High	Cheap

Groundbreaking Innovations in Glass Technology You Need to Know

Ongoing breakthroughs in material science are expected to make future iterations of Gorilla Glass even thinner, stronger, and more resistant to environmental wear.

Researchers are also exploring self-healing glass and more sustainable production methods.

Advancements in glass technology especially for smartphones and other electronic displays are pushing the limits of durability, scratch resistance, and flexibility.

Innovations in materials like Gorilla Glass, Sapphire Glass, Dragontrail Glass, and potentially Panda Glass aim to enhance protection against drops and scratches.

Corning, for example, continues refining its glass formulations, with developments like Gorilla Glass Armor offering better drop resistance and anti reflective properties.

Meanwhile, the emergence of flexible glass, such as Corning’s Willow Glass, is paving the way for foldable smartphones and other futuristic designs.

Sustainability is also becoming a priority, with manufacturers working on eco-friendly production techniques, including recycling and energy efficient manufacturing, to minimize environmental impact.

Beyond smartphones, glass technology is expanding into fields like smart eyewear, data storage, and even medical applications.

The idea of flexible glass has been around since at least the first century AD, during the reign of Tiberius Caesar though historians debate whether those early accounts were more fiction than fact. Today, however, flexible glass is a reality, albeit as a specialized material.

Corning introduced Willow Glass in 2012, a bendable glass that can be cut in large sheets using lasers.

In 2019, researchers at the University of Lyon discovered an aluminum-based glass that, unlike traditional silica based glass, can stretch at room temperature without breaking much like metal.

What does this mean for the future? Some speculate that it could revolutionize flexible electronics, potentially leading to wearable smartphones or foldable tablets that function like paper books.

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Transparent Solar Panels: The Future of Energy Generating Glass

Could glass actually generate electricity? Could your windows power your home and devices? The answer is a solid yes.

Swiss researchers have developed dye sensitized solar cells (DSCs), also known as “Grätzel cells,” which turn visible light into energy.

Early adopters are already using these transparent, low-cost solar cells in skylights, glass facades, and even greenhouses, and they come in a variety of colors, although they are not yet mainstream.

One of the most impressive applications is at the Copenhagen International School, where 12,000 blue DSCs cover a building, seamlessly blending solar energy generation into its design.

If scaled effectively, these cells could be a game changer for the renewable energy industry, offering an aesthetically pleasing alternative to traditional solar panels.

Of course, this vision is still a work in progress especially since we don’t yet have flexible batteries or bendable computer chips to match.

But who knows? Maybe one day, glass will power the world around us.

Lightweight Glass: The Evolution of Stronger, Thinner, and Greener Materials

In the 21st century, one noticeable trend in technology is the push toward slimmer, lighter materials including glass.

Modern glass is not just about aesthetics or making gadgets look sleek; it’s also a way to cut down on carbon emissions during production.

Compared to 50 years ago, today’s glass is, on average, 30% lighter and requires 70% less energy to produce. And as technology advances, it’s getting even thinner.

Ultra lightweight glass now plays a role in everything from phone screens and optical lenses to glass bottles, offering durability without the extra weight.

This innovation is partly driven by new materials, such as titanium and zirconium infused glass, which are already being used in various applications.

Industry experts predict that it won’t be long before we see these advanced glass types incorporated into windows and doors as well.

Self Healing Glass: A Breakthrough in Smart Material Technology

It might come as a surprise, but self-healing materials have been around for centuries.

The ancient Romans, for example, used a special lime based concrete that could repair its own cracks over time. But glass? That’s a different story.

Common sense tells us that once a glass surface cracks, there’s no going back right? Well, not quite.

A team of scientists from Israel and North America has developed a self-assembling, self healing glass by combining a specific peptide (a chain of amino acids) with water.

The result? A material as strong and clear as regular glass, but with the remarkable ability to heal itself. Researchers believe it could be used for glass panes, coatings, and even optical lenses.

It’s important to note that self-healing glass isn’t the same as self cleaning glass. The latter comes in two varieties hydrophobic and hydrophilic both of which use water droplets to stay spotless.

Then there’s antimicrobial glass, which is infused with silver ions that wipe out 99.9% of bacteria on the surface.

Glass technology is evolving fast, and with innovations like these, the future is looking clearer than ever literally.

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Smart Glass: The Future of Adaptive and Energy Efficient Windows

Smart glass is a remarkable material that can shift from transparent to opaque at the press of a button, offering instant privacy and versatility.

Already in use across a range of industries, smart glass is found in everything from car sunroofs and office partitions to shower doors and hospital privacy screens. It even doubles as a projector screen in offices and retail spaces, adding to its functionality.

The technology behind smart glass varies, but most types rely on microscopic elements that respond to an electric current.

When the power is off, these tiny components whether liquid crystals, metal blinds, rod like particles, or lithium ions align in a way that blocks light. Switch the current on, and they scatter, allowing light to pass through.

Beyond its futuristic appeal, smart glass is energy efficient and highly adaptable, making it a game changer for modern architecture and interior design.

Given its growing popularity, it’s only a matter of time before it becomes a standard feature in homes, offices, and public spaces.

Conclusion

Gorilla Glass has caused a revolution in modern technology. It offers exceptional strength, durability, and clarity for smartphones, tablets, and many high tech devices.

Corning’s cutting edge manufacturing methods from choosing raw materials to precise engineering and advanced coatings have made Gorilla Glass the gold standard for toughened glass.

Yet, as technology moves forward other options emerge.

Materials such as Dragontrail, Sapphire, and Panda Glass each bring their own strengths and drawbacks. This gives consumers and manufacturers a variety of choices to suit different needs.

The right glass choice depends on what the device is for and what the user expects, whether that’s scratch resistance, impact strength, or good value for money.

Past Gorilla Glass, cutting edge breakthroughs like see through solar panels glass that fixes itself, and intelligent glass point to a future where glass tech does more than protect it plays a key role in saving energy, staying green, and changing how things work.

As scientists keep digging, the next wave of glass could change how we use tech making our gadgets tougher smarter, and better for the planet.

As we keep pushing the limits of what materials can do, one thing’s for sure: the future of glass tech is just as thrilling and tough as Gorilla Glass.

Take Care.