Category Archives: Flexible Displays

Each issue of the journal Nature Electronics contains a column called “Reverse Engineering,” which examines the development of an electronic device now in widespread use from the viewpoint of the main inventor. So far, it has featured creations such as the DRAM, DVD, CD, and Li-ion rechargeable battery. The July 2018 column tells the story of the IGZO thin film transistor (TFT) through the eyes of Professor Hideo Hosono of Tokyo Tech’s Institute of Innovative Research (IIR), who is also director of the Materials Research Center for Element Strategy.

TFTs using oxides including indium (In), gallium (Ga), and zinc (Zn), or IGZO, made possible high-resolution energy-efficient displays that had not been seen before. IGZO electron mobility is 10 times that of hydrogenated amorphous silicon, which was used exclusively for displays in the past. Additionally, its off current is extremely low and it is transparent, allowing light to pass through. IGZO has been applied to drive liquid crystal displays, such as those on smartphones and tablets. Three years ago, it was also used to drive large OLED televisions, which was considered a major breakthrough. This market is rapidly expanding, as can be seen from the products being released by South Korean and Japanese electronics manufacturers, which now dominate store shelves.

The electron conductivity of transition metal oxides has long been known, but electric current modulation using electric fields has not. In the 1960s, it was reported that modulating the electric current was possible when zinc oxide, tin oxide, and indium oxide were formed into TFT structures. Their performance, however, was poor, and reports of research on organic TFTs were mostly nonexistent until around 2000. A new field called oxide electronics came into existence in the early noughties, examining oxides as electronic materials. A hub for this research was the present-day Laboratory for Materials and Structures within IIR, and research into zinc oxide TFTs soon spread worldwide. However, since the thin film was polycrystalline, there were problems with its characteristics and stability, and no practical applications were achieved.

Application in displays, unlike CPUs, requires the ability to form a thin, homogenous film on a large-sizedsubstrate — like amorphous materials — and a dramatic increase in electric current at a low gate voltage when the thin film is subjected to an electric field. However, while amorphous materials were the optimal choice for forming thin, homogeneous film, high carrier concentration and other issues due to structural disorder arose, for the most part preventing electric current modulation by electric fields. The only exception was amorphous silicon containing a large amount of hydrogen, reported in 1975. TFTs made of this material were applied to drive liquid crystal displays, which grew into a giant 10 trillion-yen industry. However, electron mobility was still lower by two to three orders of magnitude compared to that of crystalline silicon — no better than 0.5 to 1 cm2 V-1 s-1. Amorphous semiconductors, therefore, were easy to produce, but were seen to have much inferior electronic properties.

Hosono focused his attention on oxides with highly ionic bonding nature, the series made up of non-transition metals belonging to the p-block of the periodic table. In this material series, the bottom of the conduction band, which works as the path for electron, is made up mainly of spherically symmetrical metal s-orbitals with a large spatial spread. Because of this, the degree of overlap of the orbitals, which govern how easily electrons can move, is not sensitive to bond angle variation which is an intrinsic nature of amorphous materials.

The professor realized that this characteristic might allow for mobility in amorphous materials that is comparable to that of polycrystalline thin films. He experimented accordingly, and was able to find some examples. In 1995, he presented his idea and examples at the 16th International Conference on Amorphous Semiconductors, and had the paper on its proceedings published the following year. After proving this hypothesis through experiments and calculations, he started test-producing TFTs. Many combinations of elements fulfilled the conditions of the hypothesis. IGZO was selected because it had a stable crystalline phase that is easy to prepare, and its specific local structure around Ga suggested that carrier concentration could be suppressed. In 2003, Hosono and his collaborators reported in Science that crystalline epitaxial thin film could produce mobility of around 80 cm2 V-1 s-1. In the following year, they published in Nature that amorphous thin film could also produce mobility of around 10 cm2 V-1 s-1.

Following these findings, research on amorphous oxide semiconductors and their TFTs began increasing rapidly around the world — not just among the Society for Information Display (SID) and the International Conference on Amorphous Semiconductors. This activity has continued, and Hosono’s two papers have now been cited over 2,000 and 5,000 times respectively. The total citations of the patents associated with these inventions now exceed 9,000. Products with displays incorporating these TFTs have been available to the general consumers since 2012. In particular, large OLED televisions, which appeared around 2015, became possible only due to the unique characteristics of amorphous IGZO TFTs — their high mobility and ability to easily form a thin, homogenous film over a large area. Such displays are installed on the first floor of the Materials Research Center for Element Strategy and the foyer of the Laboratory for Materials and Structures at Tokyo Tech. Application of IGZO TFTs to high-definition large LCD televisions are expected to start soon.

A new manufacturing technique uses a process similar to newspaper printing to form smoother and more flexible metals for making ultrafast electronic devices.

The low-cost process, developed by Purdue University researchers, combines tools already used in industry for manufacturing metals on a large scale, but uses the speed and precision of roll-to-roll newspaper printing to remove a couple of fabrication barriers in making electronics faster than they are today.

Roll-to-roll laser-induced superplasticity, a new fabrication method, prints metals at the nanoscale needed for making electronic devices ultrafast. Credit: Purdue University image/Ramses Martinez

Cellphones, laptops, tablets, and many other electronics rely on their internal metallic circuits to process information at high speed. Current metal fabrication techniques tend to make these circuits by getting a thin rain of liquid metal drops to pass through a stencil mask in the shape of a circuit, kind of like spraying graffiti on walls.

“Unfortunately, this fabrication technique generates metallic circuits with rough surfaces, causing our electronic devices to heat up and drain their batteries faster,” said Ramses Martinez, assistant professor of industrial engineering and biomedical engineering.

Future ultrafast devices also will require much smaller metal components, which calls for a higher resolution to make them at these nanoscale sizes.

“Forming metals with increasingly smaller shapes requires molds with higher and higher definition, until you reach the nanoscale size,” Martinez said. “Adding the latest advances in nanotechnology requires us to pattern metals in sizes that are even smaller than the grains they are made of. It’s like making a sand castle smaller than a grain of sand.”

This so-called “formability limit” hampers the ability to manufacture materials with nanoscale resolution at high speed.

Purdue researchers have addressed both of these issues – roughness and low resolution – with a new large-scale fabrication method that enables the forming of smooth metallic circuits at the nanoscale using conventional carbon dioxide lasers, which are already common for industrial cutting and engraving.

“Printing tiny metal components like newspapers makes them much smoother. This allows an electric current to travel better with less risk of overheating,” Martinez said.

The fabrication method, called roll-to-roll laser-induced superplasticity, uses a rolling stamp like the ones used to print newspapers at high speed. The technique can induce, for a brief period of time, “superelastic” behavior to different metals by applying high-energy laser shots, which enables the metal to flow into the nanoscale features of the rolling stamp – circumventing the formability limit.

“In the future, the roll-to-roll fabrication of devices using our technique could enable the creation of touch screens covered with nanostructures capable of interacting with light and generating 3D images, as well as the cost-effective fabrication of more sensitive biosensors,” Martinez said.

Smart technologies take center stage tomorrow as SEMICON West, the flagship U.S. event for connecting the electronics manufacturing supply chain, opens for three days of insights into leading technologies and applications that will power future industry expansion. Building on this year’s record-breaking industry growth, SEMICON West – July 10-12, 2018, at the Moscone Center in San Francisco – spotlights how cognitive learning technologies and other disruptors will transform industries and lives.

Themed BEYOND SMART and presented by SEMI, SEMICON West 2018 features top technologists and industry leaders highlighting the significance of artificial intelligence (AI) and the latest technologies and trends in smart transportation, smart manufacturing, smart medtech, smart data, big data, blockchain and the Internet of Things (IoT).

Seven keynotes and more than 250 subject matter experts will offer insights into critical opportunities and issues across the global microelectronics supply chain. The event also features new Smart Pavilions to showcase interactive technologies for immersive, virtual experiences.

Smart transportation and smart manufacturing pavilions: Applying AI to accelerate capabilities

Automotive leads all new applications in semiconductor growth and is a major demand driver for technologies inrelated segments such as MEMS and sensors. The SEMICON West Smart Transportation and Smart Manufacturing pavilions showcase AI breakthroughs that are enabling more intelligent transportation performance and manufacturing processes, increasing yields and profits, and spurring innovation across the industry.

Smart workforce pavilion: Connecting next-generation talent with the microelectronics industry

SEMICON West also tackles the vital industry issue of how to attract new talent with the skills to deliver future innovations. Reliant on a highly skilled workforce, the industry today faces thousands of job openings, fierce competition for workers and the need to strengthen its talent pipeline. Educational and engaging, the Smart Workforce Pavilion connects the microelectronics industry with college students and entry-level professionals.

In the Workforce Pavilion “Meet the Experts” Theater, recruiters from top companies are available for on-the-spot interviews, while career coaches offer mentoring, tips on cover letter and resume writing, job-search guidance, and more. SEMI will also host High Tech U (HTU) in conjunction with the SEMICON West Smart Workforce Pavilion. The highly interactive program supported by Advantest, Edwards, KLA-Tencor and TEL exposes high school students to STEM education pathways and useful insights about careers in the industry.

AMD (NASDAQ:AMD) today announced awards for key suppliers that contributed to the successful launch of 10 new high-performance computing and graphics product families in 2017. The companies honored demonstrated commitment to AMD through excellence in delivery of material, services and technology.

“Our multi-year strategy to design and deliver high-performance products requires a team effort across our global supply chain. Our deep collaboration with our ecosystem of suppliers enables AMD to focus on bringing innovation and choice to the market,” said Keivan Keshvari, senior vice president of Global Operations for AMD. “We look forward to continuing this shared success with our suppliers as market momentum continues to grow for our Ryzen™, Radeon™ and EPYC™ products. Beyond these acknowledgements, AMD extends thanks and appreciation to its entire global network of suppliers for their role supporting our joint success.”

2017 was a successful year for AMD fueled by a record number of innovative product launches delivered to the market. The following suppliers are being recognized as those who played a leading role in enabling these results:

FlexTech, a SEMI Strategic Association Partner, is now soliciting proposals for projects that advance flexible hybrid electronics (FHE) for sensors, power and other key electronic components. SEMI-FlexTech plans to announce multiple awards to teams or organizations with research and development capability in the U.S. White paper proposals are due July 9, 2018, at 5:00 PM PDT. Review the full Request for Proposal (RFP) for more information about the submission process here.

In partnership with the U.S Army Research Laboratories (ARL), SEMI-FlexTech is seeking proposals for projects that advance heterogeneous packaging for FHE including integrated systems, system architecture and design, and integrated power management components such as batteries, supercapacitors, and energy harvesting.

SEMI-FlexTech’s Technical Council will evaluate and rank proposals, prioritize and manage projects, and administer funding. Grant recipients must match the fund award with cash and in-kind contributions to cover total project cost. Historically, grant recipients have provided, on average, more than 60 percent of project costs. A product demonstration is also required for award consideration.

“This solicitation emphasizes FHE for the Internet of Things (IoT) as we seek to advance the state of the art and incorporate thinned ICs, flexible and printed electronics, power and sensors into a flexible, conformal, low-power package,” explained Melissa Grupen-Shemansky, Executive Director and CTO of SEMI-FlexTech. “The SEMI-FlexTech program is designed to engage multi-disciplinary teams from across the supply chain to develop creative solutions that accelerate the introduction of new FHE technologies.”

SEMI-FlexTech will fund technical approaches that are revolutionary or carry high risk as well as lower-risk evolutionary approaches with shorter development and delivery timetables. SEMI-FlexTech funds research and development initiatives that fall within the U.S. government’s Technology Readiness Levels (TRLs) 3-6 and Manufacturing Readiness Levels (MRLs) 1-3.

Researchers have demonstrated large-scale fabrication of a new type of transparent conductive electrode film based on nanopatterned silver. Smartphone touch screens and flat panel televisions use transparent electrodes to detect touch and to quickly switch the color of each pixel. Because silver is less brittle and more chemically resistant than materials currently used to make these electrodes, the new films could offer a high-performance and long-lasting option for use with flexible screens and electronics. The silver-based films could also enable flexible solar cells for installation on windows, roofs and even personal devices.

In the journal Optical Materials Express, the researchers report fabrication of a transparent conducting thin-film on glass discs 10 centimeters in diameter. Based on theoretical estimations that matched closely with experimental measurements, they calculate that the thin-film electrodes could perform significantly better than those used for existing flexible displays and touch screens.

“The approach we used for fabrication is highly reproducible and creates a chemically stable configuration with a tunable tradeoff between transparency and conductive properties,” said the paper’s first author, Jes Linnet from the University of Southern Denmark. “This means that if a device needs higher transparency but less conductivity, the film can be made to accommodate by changing the thickness of the film.”

The researchers used an approach called colloidal lithography to create a silver nanopattern that conducts electricity while letting light through the holes. The new transparent electrode films could be useful for solar cells as well as flexible displays and touch screens. Credit: Jes Linnet, University of Southern Denmark

Finding a flexible alternative

Most of today’s transparent electrodes are made of indium tin oxide (ITO), which can exhibit up to 92 percent transparency — comparable to glass. Although highly transparent, ITO thin films must be processed carefully to achieve reproducible performance and are too brittle to use with flexible electronics or displays. Researchers are seeking alternatives to ITO because of these drawbacks.

The anti-corrosive nature of noble metals such as gold, silver and platinum makes them promising ITO alternatives for creating long-lasting, chemically resistant electrodes that could be used with flexible substrates. However, until now, noble metal transparent conductive films have suffered from high surface roughness, which can degrade performance because the interface between the film and other layers isn’t flat. Transparent conductive films can also be made using carbon nanotubes, but these films don’t currently exhibit high enough conductance for all applications and tend to also suffer from surface roughness due to the nanotubes stacking on top of each other.

In the new study, the researchers used an approach called colloidal lithography to create transparent conductive silver thin films. They first created a masking layer, or template, by coating a 10-centimeter wafer with a single layer of evenly sized, close-packed plastic nanoparticles. The researchers placed these coated wafers into a plasma oven to shrink the size of all the particles evenly. When they deposited a thin film of silver onto the masking layer, the silver entered the spaces between the particles. They then dissolved the particles, leaving a precise pattern of honeycomb-like holes that allow light to pass through, producing an electrically conductive and optically transparent film.

Balancing transparency and conductivity

The researchers demonstrated that their large-scale fabrication method can be used to create silver transparent electrodes with as much as 80 percent transmittance while keeping electrical sheet resistance below 10 ohms per square – about a tenth of what has been reported for carbon-nanotube-based films with the equivalent transparency. The lower the electrical resistance, the better the electrodes are at conducting an electrical charge.

“The most novel aspect of our work is that we accounted for both the transmission properties and the conductance properties of this thin film using theoretical analysis that correlated well with measured results,” said Linnet. “Fabrication problems typically make it hard to get the best theoretical performance from a new material. We decided to report what we encountered experimentally and postulate remedies so that this information could be used in the future to avoid or minimize problems that may affect performance.”

The researchers say that their findings show that colloidal lithography can be used to fabricate transparent conductive thin films that are chemically stable and could be useful for a variety of applications.

By Walt Custer, Custer Consulting Group

Broad global & U.S. electronic supply chain growth

The first quarter of this year was very strong globally, with growth across the entire electronics supply chain. Although Chart 1 is based on preliminary data, every electronics sector expanded –  with many in double digits. The U.S. dollar-denominated growth estimates in Chart 1 have effectively been amplified by about 5 percent by exchange rates (as stronger non-dollar currencies were consolidated to weaker U.S. dollars), but the first quarter global rates are very impressive nonetheless.

Walt Custer Chart 1

U.S. growth was also good (Chart 2) with Quarter 1 2018 total electronics equipment shipments up 7.2 percent over the same period last year. Since all the Chart 2 values are based on domestic (US$) sales, there is no growth amplification due to exchange rates.

Walt Custer Chart 2

We expect continued growth in Quarter 2 but not at the robust pace as the first quarter.

Chip foundry growth resumes

Taiwan-listed companies report their monthly revenues on a timely basis – about 10 days after month end. We track a composite of 14 Taiwan Stock Exchange listed chip foundries to maintain a “pulse” of this industry (Chart 3).

Walt Custer Chart 3

Chip foundry sales have been a leading indicator for global semiconductor and semiconductor capital equipment shipments. After dropping to near zero in mid-2017, foundry growth is now rebounding.

Chart 4 compares 3/12 (3-month) growth rates of global semiconductor and semiconductor equipment sales to chip foundry sales. The foundry 3/12 has historically led semiconductors and SEMI equipment and is pointing to a coming cyclical upturn. It will be interesting to see how China’s semiconductor industry buildup impacts this historical foundry leading indicator’s performance.

Walt Custer Chart 4

Passive Component Shortages and Price Increases

Passive component availability and pricing are currently major issues. Per Chart 5, Quarter 1 2018 passive component revenues increased almost 25 percent over the same period last year. Inadequate component supplies are hampering many board assemblers with no short-term relief in sight.

Walt Custer Chart 5

Peeking into the Future

Looking forward, the global purchasing managers index (a broad leading indicator) has moderated but is still well in growth territory.

Walt Custer Chart 6

The world business outlook remains positive but requires continuous watching!

Walt Custer of Custer Consulting Group is an  analyst focused on the global electronics industry.

Originally published on the SEMI blog.

Despite the low seasonality factor and brands turning their focus away from volume growth, the demand for large display panels showed better-than-expected results in the first quarter of 2018, albeit still weak, according to IHS Markit (Nasdaq: INFO).

First quarter of each year is typically a slow season for the display market as set brands try to clear out carried inventories before they launch new models in a new year. In addition, particularly this year, top-tier brands were expected to stop focusing on volume growth, which lowered market expectation on the panel demand.

However, shipments of large display panels posted better-than-expected results in the first quarter of 2018, according to Large Area Display Market Tracker by IHS Markit. Compared to a year ago, shipments of large displays — larger than 9 inches — increased by 6 percent in unit and by 10 percent in area.

LG Display retained its lead in the large display panel market in terms of area shipments with a stake of 22 percent, followed by Samsung Display with 17 percent, while, in terms of unit shipments, BOE led the market with a 22 percent share.

“In area shipments, South Korean panel makers keep their leading position in the large display market as they are strong in the TV display market,” said Robin Wu, principal analyst at IHS Markit.

Shipments of TV displays increased by 12 percent in unit and by 11 percent in area in the first quarter of 2018 compared to a year ago, leading to the better-than-expected trend. In particular, unit shipments of 55-inch and larger TV panels jumped 20 percent year on year in the first quarter. 4K TV display unit shipment also increased by 19 percent during the same period to 24.6 million units, and OLED TV display shipments reached some 600,000 units with 110 percent year-on-year growth.

051518_Large_area_display_unit_shipment_share_by_maker_in_Q1_2018 051518_Large_area_display_area_shipment_share_by_maker_in_Q1_2018

“Increases in large display panel production capacity, particularly in China, helped the year-on-year shipment growth, which was somewhat expected,” Wu said. “But, if you look at the shipment growth in a quarter-on-quarter term, it is quite interesting.”

For the past three years from 2015 to 2017, on average, unit shipments of large display declined 10 percent in the first quarters compared to the previous quarter, and area shipments were down 8 percent.

“This year also shows declines in the first quarter with a 4 percent drop in unit shipments and 7 percent down in area shipments, but the contraction is narrower than the previous years,” Wu said. “This indicates the shipment trend in first quarter 2018 was better than expected.”

051518_Large_display_shipments

Wu noted, however, that shipments dropped 10 percent in value due to continued erosion in panel price, which began in mid- 2017.

“The major concerns to the panel makers is how to achieve a turnaround in panel prices and when,” Wu said. “Trends in TV display panels that are shifting to larger sizes and heading to higher-end products can be the key to overcome the challenge.”Wu noted, however, that shipments dropped 10 percent in value due to continued erosion in panel price, which began in mid- 2017.

The Large Area Display Market Tracker by IHS Markit provides information about 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.

An international research team from Russia, France, and Germany has proposed a new method for orienting liquid crystals. It could be used to increase the viewing angle of liquid-crystal displays. The paper was published in the journal ACS Macro Letters.

“This is first and foremost a fundamental study exploring the mechanisms of liquid crystal orientation,” says Dimitri Ivanov, the head of the Laboratory of Functional Organic and Hybrid Materials at MIPT. “That said, we expect that these mechanisms might have applications in new LCD technology.”

Subpixel structure in a twisted nematic LCD. Credit: Lion_on_helium/MIPT Press Office

Subpixel structure in a twisted nematic LCD. Credit: Lion_on_helium/MIPT Press Office

Liquid crystals

Most solids are crystals. In a crystal, molecules or atoms form an ordered three-dimensional structure. Unlike solids, liquids lack this internal long-range order, but they can flow. Matter in a liquid-crystal state has properties that are intermediate between those of liquids and crystals: It possesses both the molecular order and the ability to flow. A liquid crystal can thus be viewed as an “ordered” liquid.

Not all materials can exhibit a liquid crystalline state, and the phase transition mechanisms may vary. Among other things, the molecules of an LC material have to be anisometric — that is, rod- or disk-shaped. Some compounds become LCs in a certain temperature range. These are called thermotropic. By contrast, lyotropic LCs adopt the liquid crystalline state when a solvent is added.

The properties of an LC material vary depending on the direction. For example, polarized light propagates in a liquid crystal at different speeds along different directions. Also, in an electric or magnetic field, the orientation of LCs can rapidly change. This phenomenon is known as the Fréedericksz transition. Thanks to the optical properties of LCs and their ability to be easily realigned, they are widely used in the electronic displays of TVs, computers, phones, and other devices.

Liquid-crystal displays

In an LCD, the image is generated by changing the intensity of light in each pixel via an electric field, which realigns liquid crystals. There are several LCD configurations, but the one most commonly used is based on twisted nematic LCs. These are rod-shaped thermotropic liquid crystals that can adopt a twisted configuration by using special aligning substrates. Applying an electric field to these LCs can untwist them. This reproducible and predictable response can be used to control light intensity.

Each pixel in a color LCD consists of three subpixels: red, green, and blue. By varying their intensities, any color can be displayed. A subpixel in a twisted nematic-based LCD (figure 1) consists of a light source, a color filter, two polarizers, and an LC cell between two glass plates with electrodes. If the liquid crystals were not there, no light would pass through the cell, because whatever light is let through by the vertical polarizer would be blocked by the horizontal polarizer before reaching the color filter. However, special substrates with groovy surfaces can be used to twist LCs in a spiral between two polarizers so as to turn the light precisely by the amount needed to pass through the second polarizer. The fully illuminated state of the subpixel is actually its “off” state. When voltage is applied, the liquid crystals untwist, changing the light polarization to a lesser degree. As a result, some of the light is blocked. Eventually, as some voltage no light can reach the color filter, and the subpixel goes dark.

One of the limitations of this technology is the viewing angle of a display: From a sideways perspective, the LCD will not render the colors accurately. This is due to the co-alignment of liquid crystals. The issue can be solved using multidomain displays, in which pixels belong to a number of domains, whose LC orientations are different. This means that at least some of the domains are always oriented in the right way. The international team of researchers led by Professor Dimitri Ivanov, who heads MIPT’s Laboratory of Functional Organic and Hybrid Materials, has proposed a brand new solution for multidomain display design.

Going orthogonal

The authors of the paper reported in this story worked with liquid-crystal polymers. These are substances composed of long molecules with chainlike repetitive structure. It turned out that a slight variation in the structure of polymers can drastically alter their orientation on the substrate. The polymers used in the study are poly(di-n-alkylsiloxanes), or PDAS. Each molecule is a chain containing alternating silicon and oxygen atoms. The silicon atoms in PDAS bear two symmetric hydrocarbon side chains (figure 2). The n in the name of the compound stands for the length of the side chains, which was varied between 2 and 6.

In the experiment, polymers from the PDAS family were deposited on a Teflon-rubbed aligning surface with a regular pattern of grooves. Generally, crystalline polymers are known to align on such substrates, but only when the lattice parameters of the substrate match those of the deposited polymer. The researchers examined the orientation of the liquid-crystal polymer chains relative to the direction of the grooves on the aligning surface. The side chain length n was increased in steps of just one methylene group (CH?) at a time.

It was found that, contrary to expectations, the liquid-crystal orientation varied depending on side-chain length. At n equal to 2, the needlelike polymer superstructures known as lamellae co-aligned with the Teflon grooves. Because lamellae are known to be perpendicular to the polymer chains, the researchers concluded that the polymer chains are perpendicular to the grooves on the substrate (figure 3, left). When n was increased to 3, the orientation of the lamellae changed by 90 degrees, making them perpendicular to the grooves. As a result, the LC polymer chains were now oriented parallel to the grooves (figure 3, right). At n equal to 4, no further change in orientation was observed. However, when the side-chain length was further increased to 5 and 6, the lamellae again co-aligned with the Teflon grooves.

The researchers have thus found that by merely adding one methylene group to the side chain of the polymer, they could switch the LC orientation, which is crucial for most applications of liquid crystals, including LCDs. According to the authors, the effect they discovered could be used to design LCDs with improved viewing angles. This could be achieved using a multidomain technology that works by orienting subpixels of one color in different directions. As a result, the pixels compensate one another when the display is viewed at an angle, improving color rendition. The researchers expect this technology to be considerably simpler and cheaper than other multidomain approaches that are currently used.

Engineering and physics researchers at North Carolina State University have developed a new technology for steering light that allows for more light input and greater efficiency – a development that holds promise for creating more immersive augmented-reality display systems.

At issue are diffraction gratings, which are used to manipulate light in everything from electronic displays to fiber-optic communication technologies.

“Until now, state-of-the-art diffraction gratings configured to steer visible light to large angles have had an angular acceptance range, or bandwidth, of about 20 degrees, meaning that the light source has to be directed into the grating within an arc of 20 degrees,” says Michael Escuti, a professor of electrical and computer engineering at NC State and corresponding author of a paper on the work. “We’ve developed a new grating that expands that window to 40 degrees, allowing light to enter the grating from a wider range of input angles.

“The practical effect of this – in augmented-reality displays, for example – would be that users would have a greater field of view; the experience would be more immersive,” says Escuti, who is also the chief science officer of ImagineOptix Corp., which funded the work and has licensed the technology.

The new grating is also significantly more efficient.

“In previous gratings in a comparable configuration, an average of 30 percent of the light input is being diffracted in the desired direction,” says Xiao Xiang, a Ph.D. student at NC State and lead author of the paper. “Our new grating diffracts about 75 percent of the light in the desired direction.”

This advance could also make fiber-optic networks more energy efficient, the researchers say.

The new grating achieves the advance in angular bandwidth by integrating two layers, which are superimposed in a way that allows their optical responses to work together. One layer contains molecules that are arranged at a “slant” that allows it to capture 20 degrees of angular bandwidth. The second layer is arranged at a different slant, which captures an adjacent 20 degrees of angular bandwidth.

The higher efficiency stems from a smoothly varying pattern in the orientation of the liquid crystal molecules in the grating. The pattern affects the phase of the light, which is the mechanism responsible for redirecting the light.

“The next step for this work is to take the advantages of these gratings and make a new generation of augmented-reality hardware,” Escuti says.

The paper, “Bragg polarization gratings for wide angular bandwidth and high efficiency at steep deflection angles,” is published in the journal Scientific Reports. The paper was co-authored by Jihwan Kim, a research assistant professor of electrical and computer engineering at NC State.