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Despite unit-shipment declines, large thin-film transistor (TFT) liquid crystal display (LCD) shipment area is expected to grow 5 percent year over year, to reach 168 million square meters in 2016. Due to lower demand for both TV and IT panels, unit-shipment growth is expected to decline 5 percent to 656 million units in 2016, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight. LG Display will lead large TFT LCD area shipment growth in 2016 with 25 percent market share, followed by Samsung Display with 20 percent share. IHS defines large displays are those that are nine inches and larger.

TV panel unit shipments are expected to fall nearly 7 percent in 2016, while shipment area is expected to grow 7 percent, as panel makers respond to slowing demand and migrate production to larger displays, according to the latest IHS Large Area Display Market Tracker. Unit shipments of PC displays are also expected to fall 7 percent.

“Falling prices are causing panel makers to focus on the most profitable products, including larger displays and those employing newer display technologies,” said Yoonsung Chung, director of large area display research for IHS Technology. “From the panel maker’s perspective, area shipment is more important than unit shipments, so panel makers are accelerating the migration to larger TV panel sizes and higher resolutions.”

Display manufacturers are targeting a 24 percent year-over-year growth rate for 48-inch-and-larger panel sizes, which are expected to reach 93 million units in 2016. 4K LCD TV panels are expected to grow 73 percent in 2016, reaching 66 million units.

Chinese panel makers buck the tide

Because of ongoing production-capacity expansion, China is the only country expected to experience positive unit-shipment growth in 2016 in the large display segment. Chinese panel makers will enjoy 37 percent shipment-area growth and 12 percent unit-shipment growth in 2016, compared to the previous year. Area-shipment growth in South Korea will rise 2 percent, year over year.

“China’s power in the large TFT-LCD market is growing,” Chung said. “This trend could accelerate the shift to AMOLED by tier-one panel makers quicker than expected.”

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Large AMOLED displays on the rise

TV panels will drive growth in large active-matrix light-emitting diode (AMOLED) area shipments, growing 124 percent year over year to reach one million square meters in 2016. In fact, TV is expected to comprise 92 percent of total large AMOLED panel shipments by area in 2016. However, unit-shipment growth is expected to decline slightly, due to slower demand from the tablet PC category. Large AMOLED unit shipments are forecast to fall 5 percent, year over year, to reach 3.7 million in 2016.

The IHS Large Area Display Market Tracker explores the entire range of large display panels shipped worldwide and regionally, including monthly and quarterly revenues and shipments by display area, application, size and aspect ratio for each supplier.

FlexTech, a SEMI Strategic Association Partner, today announced the formal completion of three flexible hybrid electronics (FHE) R&D projects under its U.S. Army Research Laboratory  (ARL) technology investment agreement.  The completed projects are with ENrG for a flexible ceramic substrate; nScrypt and NovaCentrix for a next-generation three-dimensional (3D) printing tool for creating complex and functional objects; and PARC, a Xerox company, for a flexible sensor platform. Projects ranged from 12-18 months and were managed by a member of the FlexTech Technical Council, which is a team of experts in flexible, hybrid and printed electronics technologies.

  • ENrG, located in Buffalo, New York, completed a 15 month project to develop a high-yield process to create a 20 micron thick, flexible ceramic substrate capable of retaining its integrity when drilled, cut, rolled and processed at high temperatures. During the project, ENrG developed processes to print thin-film lithium batteries, circuits, application of copper cladding and other metallization with excellent performance characteristics. The project, valued at $570,000 total, was 56% cost shared by the company.
  • nScrypt, based in Orlando, Florida, in partnership with NovaCentrix of Austin, Texas, developed a 3D printer for rapid prototyping of new electronic devices. The total award of $1,291,000 was cost-shared by nScrpyt, NovaCentrix and FlexTech and it was completed over a 16-month period. The new tool additively builds integrated hybrid circuits on 3D surfaces, as well as devices on flexible, low temperature, and rigid planar substrates. It integrates processing of three previously-separate tools. The first tool has been installed at ARL. Commercial tools are available from nScrypt.
  • PARC, a Xerox Company, Palo Alto, California, developed a passively powered, digitally-fabricated, communication-enabled, flexible sensor platform that is easily customizable to multiple sensor types. The project addressed the availability of an end-to-end system design that can be manufactured in large quantities with digital printing for smart tag or wearable applications. In its final report, the PARC researchers noted several key areas where additional development would be helpful, including components designed specifically to be compatible with flexible, printed sensor systems. Total cost was $409,000 and shared equally between PARC and FlexTech.

“Each of these projects, chosen and supported by the Technical Council, moves the needle on learning how to fabricate electronics on flexible substrates,” stated Michael Ciesinski, president of FlexTech. “Especially impressive is the teaming on the projects, which helps build out the FHE supply chain.”

FlexTech, a SEMI Strategic Association Partner, is focused on growth, profitability, and success throughout the manufacturing and distribution chain of flexible hybrid electronics, by developing solutions for advancing these technologies from R&D to commercialization. Learn more at www.nscrypt.comwww.novacentrix.comwww.enrg-inc.comwww.parc.com

For more information, visit www.semi.org

Research published in the journals Materials Today Communications and Scientific Reports has described how silver nanowires are proving to be the ideal material for flexible, touch-screen technologies while also exploring how the material can be manipulated to tune its performance for other applications. Currently, touch screen devices mainly rely on electrodes made from indium tin oxide (ITO), a material that is expensive to source, expensive to process and very brittle.

A team from the University of Surrey, led by Professor Alan Dalton and in collaboration with M-SOLV Ltd, a touch-sensor manufacturer based in Oxford, looked to alternative materials to overcome the challenges of ITO, which is suffering from supply uncertainty. Alternative materials investigated as ITO replacements have included graphene, carbon nanotubes and random metal nanowire films. This study showed how silver nanowire films have emerged as the strongest competitor, due to transmittances and conductivities which can match and readily exceed those of ITO. This is a material that consists of wires which are over a thousand times thinner than a human hair, that form an interconnected conductive network.

Matthew Large, the first author on the research published in Scientific Reports described the importance of these latest results. “Our research hasn’t just identified silver nanowires as a viable replacement touchscreen material, but has gone one step further in showing how a process called ‘ultrasonication’ can allow us to tailor performance capabilities. By applying high frequency sound energy to the material we can manipulate how long the nanosized ‘rods’ of silver are. This allows us to tune how transparent or how conductive our films are, which is vital for optimising these materials for future technologies like flexible solar cells and roll-able electronic displays.”

In a paper published last month in Materials Today Communications, the same team, showed how silver nanowires can be processed using the same laser ablation technique commonly used to manufacture ITO devices. Using this technique, the team produced a fully operating five inch multi-touch sensor, identical to those typically used in smartphone technology. They found it performed comparably to one based on ITO but used significantly less energy to produce.

“Not only does this flexible material perform very well, we have shown that it is a viable alternative to ITO in practical devices,” concluded Professor Dalton. “The fact we are able to produce devices using similar methods as currently in use, but in a less energy-intensive way is an exciting step towards flexible gadgets that do not just open the door for new applications, but do so in a much greener way.”

Maria Cann, a technologist from M-SOLV and first author on the Materials Today Communications paper added “”We are seeing a lot of interest from our customers in silver nanowire films as an ITO replacement in devices. This work is a really important step in establishing exactly which sensor designs can make good nanowire products. The fact that the nanowire films are processed by the same laser techniques as ITO makes the transition from ITO to nanowires really straightforward. It won’t be long before we are all using nanowires in our electronic devices. ”

The team, now based at the University of Sussex is now looking to develop the scalability of the process to make it more industrially viable. One limiting factor is the current cost of silver nanowires. Funded by Innovate UK and EPSRC, the team are collaborating with M-SOLV and a graphene supplier Thomas Swan to use a nanowire and graphene combination in the electrodes to markedly reduce the cost.

Active matrix organic light-emitting diode (AMOLED) displays are rising fast, thanks to lowering costs, wider use in end-market consumer electronics devices and the ramp-up of new manufacturing capacities.  While liquid crystal display (LCD) technology is still the dominant technology in the display industry, AMOLED display shipments will grow 40 percent, year over year, to reach 395 million units in 2016. AMOLED display revenue is expected to increase by 25 percent, to reach $15 billion in 2016, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight.

“AMOLED is becoming the shiniest spot in the flat-panel display industry,” said David Hsieh, senior director, displays at IHS Technology. “AMOLED has a simpler structure than LCD, as well as a thinner and lighter form factor, better color saturation, greater contrast ratio, faster response time and easier integration with touch functions. In addition, AMOLED is formed on a polymer base substrate, allowing it to be flexible, bendable and even foldable. The organic electro-luminescence materials can be formed using a soluble printing process, which means AMOLED has the potential to be produced at a very low cost.”

Many of the obstacles to AMOLED development, such as production inefficiencies, yield-rate management issues, higher investment costs and a short lifetime for light emitting materials, were also resolved in 2015, improving the production. OLED has started to find its niche in many applications, especially in smartphones, smartwatches, automotive displays, home appliances, near-eye virtual reality (VR) devices and televisions. “Improvements in production and lowering costs are attracting more device makers to install AMOLED displays in their products,” Hsieh said.

For example, Samsung Electronics has been using AMOLED as an important differentiator in its proprietary Galaxy smartphones. Since the second half of 2015, more smartphone brands — especially manufacturers in China — have installed AMOLED displays in their devices, such as Google, Microsoft, Meizhu, Blackberry, Huawei, HTC, ZTE, Oppo and Coolpad. The 5-inch high-definition (HD), 5.5-inch full high definition (FHD), 5.5-inch and 6-inch wide quad high definition (WQHD) will be the major AMOLED smartphone display driving forces in 2016.

AMOLED penetration in smartphone displays is expected to rise from 17 percent in 2015 to 21 percent this year. Apple is reported to be considering AMOLED as a display source for its new iPhone in late 2017, replacing the current low-temperature polysilicon (LTPS) thin-film transistor (TFT) LCD display. “If Apple actually starts using AMOLED displays, the transition will be viewed as a milestone in flexible form factor development,” Hsieh said.

AMOLED_Chart_LG_IHS

According to the IHS OLED Display Market Tracker, OLED TV shipments will further expand in 2016, thanks to process improvements and production efficiency enhancements, as well as improvements in organic light emitting materials layers. In fact, LG Display is already expanding its AMOLED TV panels to 65 inches with ultra-high definition (UHD), which will bring AMOLED into the high-end TV segment. IHS expects OLED TV display shipments will grow 125 percent, year over year, to reach 900,000 units in 2016.

Tablet and notebook PCs is another important venue for AMOLED, for its slim and light form factor, and high resolution. We expect to see 8-inch and 9.7-inch quad extended graphics array (QXGA) displays and 12-inch AMOLED panels begin to emerge in the mobile PC arena this year. Many PC brands are planning to use AMOLED in notebook PCs and two-in-one convertible mobile PC models beginning in 2016. AMOLED mobile PC panels are expected to grow 63 percent year over year, to reach to 8.6 million units in 2016.

AMOLED is also leading other display technologies when it comes to response time and power consumption, which is extremely useful in near-eye display devices, including VR and augmented reality (AR) devices. AMOLED display and OLED on silicon projection displays, which are both used in near-eye displays are forecast to grow 119 percent, year over year, to reach 3.6 million units in 2016.

“The central information display in cars will also feature AMOLED within the next couple of years,” Hsieh said, “AMOLED displays provide features that are useful in automotive display applications, because of their high contrast ratio, flexible and curved form factors as well as better color gamut. Aside from these applications, AMOLED also presents great opportunities for industrial applications, home appliances, digital signage and broadcasting.”

AMOLED, as a rapidly emerging display technology, will be a key theme in the coming SID Display Week 2016 Business Track, which is co-organized by IHS and the Society for Information Display. For more information, visit SID Display Week.

With consumers becoming increasingly comfortable using smartphones and tablet PCs, touch screens are now increasingly making their way into their vehicles, too. In fact, the automotive touch panel market is expected to expand from 28 million units shipped in 2013 to 86 million in 2021, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight.

“Projected capacitive touch technology is commonly found in consumer smartphones and tablets, which consumers have grown very comfortable using,” said Shoko Oi, senior display analyst at IHS Technology. “Although there are concerns about how direct touch operations could affect safety while driving, automotive touch panels are becoming a standard feature in new vehicles coming to market.”

The content shown on automotive displays now comes from a variety of sources, both inside and outside the car. Many of these applications require touch panels, which shift the role of the display from simply revealing information visually to becoming an actual human-machine interface. This shift, along with the increased volume and importance of displayed data, is leading to a growing need for easy-to-see designs that incorporate larger sizes, irregular or curved shapes and higher resolutions.

Technological evolution hits automakers

Automotive touch panels are shifting from resistive-touch to capacitive-touch technology, and capacitive touch screens are forecast to exceed resistive touch-screens in vehicles in 2017, according to the IHS Automotive Touch Panel Market Report. As vehicle models are updated, the resistive touch screens that formerly dominated the automotive industry are quickly being replaced by capacitive touch screens.

“In spite of higher module costs, projected capacitive technology is replacing resistive technology as the mainstream touch solution for automotive monitors,” Oi said. “The latest trends in connected cars and telematics encourage car makers to adopt projected capacitive touch screens, because they provide a similar user experience to smartphone and tablet-PC touch displays.”

The IHS Automotive Touch Panel Market Report analyzes all aspects of current touch technologies, plus those being considered for future automotive applications. It includes market historical and forecast analyses by technology, sensor type, size, maker, and price.

Year-over-year unit-shipment growth in the small and medium display market was flat in 2015, reaching 2.8 billion units; revenue rose 4 percent over the previous year, to reach $43.9 billion. Samsung Display led the 9-inch-and-smaller display market in 2015, with 23 percent of all revenue, followed by Japan Display at 16 percent, LG Display at 13 percent and Sharp at 10 percent, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight.

While overall small-medium display unit shipments did not grow in 2015, increasing demand for high-resolution smartphone displays caused active-matrix organic light-emitting diode (AMOLED) display unit shipments to grow 54 percent, and low-temperature polysilicon thin-film transistor (LTPS TFT) LCD display unit shipments to rise 10 percent, over the previous year. As AMOLED and LTPS TFT LCD shipments rose, however, amorphous silicon (a-Si) TFT LCD shipments declined 10 percent year over year in 2015, according to the latest IHS Small-Medium Display Market Tracker.

“To compete in the increasingly saturated small-medium display market, smartphone manufacturers are shifting from a-Si TFT display technology to high-performance displays that rely on AMOLED and LTPS TFT technology,” said Hiroshi Hayase, senior director, IHS Technology. “In fact, with Apple’s iPhone line reportedly relying on AMOLED in the future, Japan Display and Sharp officially announced that by 2018 they would invest in mass production of AMOLED displays, joining leading AMOLED suppliers Samsung Display and LG Display.”

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As the mobile phone market slows, display manufacturers are looking to new in-cell and on-cell touch-screen solutions that offer consumers thinner and brighter displays, while shortening the supply chain for smartphone manufacturers. As panel makers promote these new solutions, and offer aggressive pricing as well, in-cell and on-cell touch solutions are expected to comprise half of all smartphone displays shipped in 2017, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight.

With the advent of active-matrix organic light-emitting diode (AMOLED) used in smartphones, new touch solutions are emerging that boast greater flexibility, lighter weight and other feature improvements. Emerging touch solutions for flexible displays are expected to grow more than 50 percent in 2016 compared to the previous year, which will bolster revenue levels, according to the latest IHS Touch Panel Market Tracker.

“Since Samsung announced their Galaxy S6 Edge smartphone last year, flexible displays have grabbed consumer and industry attention,” said Calvin Hsieh, director of display research for IHS Technology. “Flexible AMOLED displays offer many more features than traditional rigid AMOLED and LCD displays, which is an attractive proposition for device makers and consumers.”

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Liquid crystals, discovered more than 125 years ago, are at work behind the screens of TV and computer monitors, clocks, watches and most other electronics displays, and scientists are still discovering new twists–and bends–in their molecular makeup.

Liquid crystals are an exotic state of matter that flows like a fluid but in which the molecules may be oriented in a crystal-like way. At the microscopic scale, liquid crystals come in several different configurations, including a naturally spiraling “twist-bend” molecular arrangement, discovered in 2013, that has excited a flurry of new research.

Now, using a pioneering X-ray technique developed at the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab), a research team has recorded the first direct measurements confirming a tightly wound spiral molecular arrangement that could help unravel the mysteries of its formation and possibly improve liquid-crystal display (LCD) performance, such as the speed at which they selectively switch light on or off in tiny screen areas.

Researchers examined the spiral 'twist-bend' structure (right) formed by boomerang-shaped liquid crystal molecules (left and center) measuring 3 nanometers in length, using a pioneering X-ray technique at Berkeley Lab's Advanced Light Source. A better understanding of this spiral form, discovered in 2013, could lead to new applications for liquid crystals and improved liquid-crystal display screens. (Credit: Zosia Rostomian/Berkeley Lab; Physical Review Letters, DOI: 10.1103/PhysRevLett.116.147803; Journal of Materials Chemistry C, DOI: 10.1039/C4TC01927J)

Researchers examined the spiral ‘twist-bend’ structure (right) formed by boomerang-shaped liquid crystal molecules (left and center) measuring 3 nanometers in length, using a pioneering X-ray technique at Berkeley Lab’s Advanced Light Source. A better understanding of this spiral form, discovered in 2013, could lead to new applications for liquid crystals and improved liquid-crystal display screens. (Credit: Zosia Rostomian/Berkeley Lab; Physical Review Letters, DOI: 10.1103/PhysRevLett.116.147803; Journal of Materials Chemistry C, DOI: 10.1039/C4TC01927J)

The findings could also help explain how so-called “chiral” structure–molecules can exhibit wildly different properties based on their left- or right-handedness (chirality), which is of interest in biology, materials science and chemistry–can form from organic molecules that do not exhibit such handedness.

“This newly discovered ‘twist-bend’ phase of liquid crystals is one of the hottest topics in liquid crystal research,” said Chenhui Zhu, a research scientist at Berkeley Lab’s Advanced Light Source (ALS), where the X-ray studies were performed.

“Now, we have provided the first definitive evidence for the twist-bend structure. The determination of this structure will without question advance our understanding of its properties, such as its response to temperature and to stress, which may help improve how we operate the current generation of LCDs.”

Zhu was the lead author on a related research paper published in the April 7 edition of Physical Review Letters.

While there are now several competing screen technologies to standard LCDs, the standard LCD market is still huge, representing more than one-third of the revenue in the electronic display market. The overall display market is expected to top $150 billion in revenue this year.

The individual molecules in the structure determined at Berkeley Lab are constructed like flexible, nanoscale boomerangs, just a few nanometers, or billionths of a meter, in length and with rigid ends and flexible middles. In the twist-bend phase, the spiraling structure they form resembles a bunch of snakes lined up and then wound snugly around the length of an invisible pole.

Zhu tuned low-energy or “soft” X-rays at the ALS to examine carbon atoms in the liquid crystal molecules, which provided details about the molecular orientation of their chemical bonds and the structure they formed. The technique he used for the study is known as soft X-ray scattering. The spiraling, helical molecular arrangement of the liquid crystal samples would have been undetectable by conventional X-ray scattering techniques.

The measurements show that the liquid crystals complete a 360-degree twist-bend over a distance of just 8 nanometers at room temperature, which Zhu said is an “amazingly short” distance given that each molecule is 3 nanometers long, and such a strongly coiled structure is very rare.

The driving force for the formation of the tight spiral in the twist-bend arrangement is still unclear, and the structure exhibits unusual optical properties that also warrant further study, Zhu said.

Researchers found that the spiral “pitch,” or width of one complete spiral turn, becomes a little longer with increasing temperature, and the spiral abruptly disappears at sufficiently high temperature as the material adopts a different configuration.

“Currently, this experiment can’t be done anywhere else,” Zhu said. “We are the first team to use this soft X-ray scattering technique to study this liquid-crystal phase.”

Standard LCDs often use nematic liquid crystals, a phase of liquid crystals that naturally align in the same direction–like a group of compass needles that are parallel to one another, pointing in one direction.

In these standard LCD devices, rod-like liquid crystal molecules are sandwiched between specially treated plates of glass that cause the molecules to “lie down” rather than point toward the glass. The glass is typically treated to induce a 90-degree twist in the molecular arrangement, so that the molecules closest to one glass plate are perpendicular to those closest to the other glass plate.

It’s like a series of compass needles made to face north at the top, smoothly reorienting to the northeast in the middle, and pointing east at the bottom. This molecularly twisted state is then electrically distorted to allow polarized light to pass through at varying brightness, for example, or to block light (by straightening the twist completely).

Future experiments will explore how the spirals depend on molecular shape and respond to variations in temperature, electric field, ultraviolet light, and stress, Zhu added.

He also hopes to explore similar spiraling structures, such as a liquid crystal phase known as the helical nanofilament, which shows promise for solar energy applications. Studies of DNA, synthetic proteins, and amyloid fibrils such as those associated with Alzheimer’s disease, might help explain the role of handedness in how organic molecules self-assemble.

With brighter, more laser-like X-ray sources and faster X-ray detectors, it may be possible to see details in how the spiraling twist-bend structure forms and fluctuates in real time in materials, Zhu also said.

“I am hoping our ongoing experiments can provide unique information to benefit other theories and experiments in this field,” he noted.

Instead of reading a label, consumers could be interacting with an electronic screen on packaging in the future, thanks to a revolutionary new development by scientists at the University of Sheffield.

The scientists collaborated with technology company Novalia to create a new way of displaying information on packaging, a move that could revolutionise the packaging industry.

This technology could be used in greetings cards or products where a customer could receive a simple message. More complex developments could include a countdown timer on the side of a packet to indicate when a timed product was ready – such as hair-dye, pregnancy tests or home-baking using a ‘traffic lights’ system.

In a paper published in the IEEE Journal of Display Technology, the team explain how a screen can be fixed onto packaging to display information.

The process involves printing electronic tracks onto paper and then fixing low-cost electronics and a polymer LED display to the paper using an adhesive that conducts electricity.

Working together, University of Sheffield scientists and Novalia also designed and constructed a touch-pad keyboard on the paper that allows a user to selectively ‘drive’ the LEDs in the display.

The research has been funded by the Engineering and Physical Sciences Research Council (EPSRC) and testing so far has taken place on paper but the process could potentially be printed on other surfaces.

The team’s next steps are to create fully flexible organic displays on a plastic substrate that then fix onto the electronic tracks. The LED devices need to be low-cost and flexible enough to be used on all packaging.

Professor David Lidzey from the University’s Department of Physics and Astronomy said: “Labels on packaging could become much more innovative, and allow customers to interact with and explore new products. The use of displays or light emitting panels on packaging will also allow companies to communicate brand awareness in a more sophisticated manner.”

Chris Jones from Novalia said: “The paper-based packaging industry is worth billions of dollars. This innovative system we have developed with the University of Sheffield could give manufacturers a way to gain market share by being able to distinguish its products from competitors.”

Unit demand for display glass used for liquid crystal display (LCD) TVs, desktop monitors, mobile PCs and other major large panel applications is forecast to fall in 2016. However average diagonal screen sizes for each application are expanding, which means display glass area demand will continue to increase, even as unit shipments decrease. Total LCD glass capacity is now matching glass area demand, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight.

Area demand for glass used in LCD panels is forecast to rise at a compound annual growth rate (CAGR) of 13 percent from 2015 to 2018. Average LCD TV screen size is expected to increase from 39.3 inches in 2015 to 40.8 inches in 2016, according to the latest quarterly IHS Display Glass Market Tracker.

“Because manufacturing LCD glass requires special tanks for the LCD substrates used in processing, the manufacturing cost of LCD glass is higher than for other materials, and tank investment can be a risky proposition for glass makers,” said Tadashi Uno, senior analyst, IHS Technology. “For these reasons, LCD glass manufacturers are looking to increase the capacity of existing tanks, rather than making additional investments in new tanks.”

As competition in this market intensifies, panel makers are suffering from module price reductions. As profits decline, major large panel makers are not only pressuring vendors to reduce the costs of materials and components, they are also trying to save on glass costs by manufacturing thinner LCD glass. Between 2012 and 2014, major panel makers successfully shifted glass substrate thickness from 0.7 millimeters to 0.5 millimeters; panel makers are now trying to create display glass that is even thinner, decreasing thickness from 0.5 millimeters to 0.4 millimeters. “Samsung is the first company out of the gate with these new efforts, but other major panel makers will soon follow,” Uno said.