Category Archives: Displays

“As TV makers struggle to trigger replacement cycles, WCG and HDR and their notable picture quality improvements are the next growth drivers for the TV industry,” announced Eric Virey, Senior Market & Technology Analyst, LED, Sapphire & Displays at Yole Développement (Yole).

Various technologies are competing to deliver those features. In the short and mid-term, the best-positioned ones are OLED and the well-established, dominant, LCD technology supercharged with narrow-band phosphor LEDs or QD color converters in the backlight unit. Yole analysts delivered a deep analysis of the WCG display and QD technologies, status and prospects, roadblocks and key players with a dedicated technology & market report titled: Quantum Dots & Wide Color Gamut Display Technologies.

What is the status and benefits of QD technologies? After QD-Vision demise, what are the companies that can answer to the demand of the fast growing LCD market? How will the competitive landscape evolve, especially with OLED solutions?

wide color gamut

The “More than Moore” market research and strategy consulting company Yole offers you a snapshot of the QD technologies, its applications and the players involved.

Quantum Dots enable drastic enhancements of display color gamut. They do so with high efficiency, giving display makers headroom to increase brightness, contrast and gamut without increasing power consumption.

Their most common implementation is as color conversion films located in the LCD backlight unit. In this form, QDs are drop-in solutions that can be easily deployed on all sizes of displays without any process change or CapEx . QDs therefore enable the LCD industry to boost the performance of its products without major investment. This contrasts with OLEDs, which require building multibillion-dollar dedicated fabs.

However, QDs do not solve some of LCD shortcomings. Mostly, LCD still lag behind OLEDs in terms of response times, black levels and viewing angles. Also, LCDs cannot deliver pixel-level dimming, the strongest selling point for OLED displays. In the near future, QDs could substitute for LCD color filters. Unlike films, this configuration requires some process changes in LCD manufacturing.

However, it would double the display efficiency, further improve color gamut and provide viewing angles similar to OLED.

In the longer term, EL-QD could deliver OLED-like characteristics and performance, with improved brightness and stability.

“QDs and related technologies will take advantage of OLED TV capacity constraints,” says Dr Eric Virey from Yole.

LG Display is currently the only OLED TV panel manufacturer. The company announced that it will stop investing in LCD and build two new OLED TV manufacturing lines in Korea and China, slated to start production in late 2019. Cost and technology barriers to entry are high, and few other companies will be able to manufacture OLED TV panels in that timeframe. Unless OLED printing technologies progress fast enough to enable cost efficient manufacturing of large, full RGB displays, OLED TV adoption will therefore remain capacity-constrained to less than 12 million units per year until 2022.

QDs will take advantage of this window of opportunity to capture the lion’s share of the WCG and HDR TV market. Rapidly improving performance and decreasing cost is already enabling adoption to spread into mid-range, sub-US$1000 models opening a high volume markets still forbidden to OLED for cost and capacity reasons. Display makers will use QDs to keep extracting more value from existing LCD fab. For the long term, many are hedging their bets and looking at both RGB printed OLED and EL-QDs.

In the mid-term however, QDCF configurations represent an attractive opportunity to close the gap with OLED in term of viewing angles and widen it in term of gamut and efficiency. QDCF however requires some LCD manufacturing process changes. Although moderate compared to a new OLED fab, not every LCD maker will want to commit the required CapEx or even develop the technology.
In the longer term, both OLED and QD-enhanced LCD could face competition from new, disruptive technologies such as the already mentioned electroluminescent QDs or even microLEDs, which could drive a potential paradigm shift, offering alternatives to OLED in self-emissive display technologies. Other technological innovations could also disrupt the QD market. For example, commercialization of a narrow-band green phosphor could eliminate the performance gap between phosphors and QD films and enable a more cost-effective solution.

The overall utilization rate of display panel fabrication (fab) plants is expected to remain high in the third quarter of 2017, recording similar levels for the fifth consecutive quarter, according to IHS Markit (Nasdaq: INFO).

Figure 1

Figure 1

According to the latest Display Production & Inventory Tracker by IHS Markit, the overall fab utilization rate is expected to reach 91 percent in the third quarter, up 1.8 percentage points from the previous quarter and up 1.1 percentage points from the same period last year.

Figure 2

Figure 2

“One of the main contributing factors for higher utilization rates in the past few quarters is that display panel makers are making sure their inventories are optimized at healthy levels,” said Alex Kang, senior analyst at IHS Markit.

Production of large LCD panels, which take the majority of overall display production in terms of area, is expected to be 2.2 percent higher than actual shipments in the third quarter. This is a result of display makers wanting to build contingency, or wriggle room, in their utilization plans as part of their strategy to offset any unexpected lower utilization rates, which could trigger off higher costs.

“As a result, panel makers’ inventory will increase, but it will still remain within healthy ranges,” Kang said.

According to IHS Markit, panel makers are expected to keep high utilization rate throughout the second half of 2017. As production capacity increase has slowed down and panel makers are expected to keep managing inventory levels within healthy limits, they will still have some room to stock up from production surplus volumes.

SparkLabs Group, a network of accelerators and funds, is launching a $50 million early-stage fund (Series A & B) primarily focused on South Korea. The fund will be led by Brian Kang, who was a founding member of Samsung’s first venture capital arm and later led Korea Venture Fund, which was Korea’s first VC fund of funds. He has over 20 years of experience as an investment professional and several years as an entrepreneur and operator. He was CEO & Chairman of the Board at Gravity, a Softbank affliated gaming company, and then went on to launch his own gaming startup.

Brian is joined by Chris Koh, Co-founder of Coupang which is the leading ecommerce player in South Korea and received $1 billion investment from Softbank in 2015. Chris started Coupang with a classmate from Harvard Business School and their friend at Harvard Law. He was vice president of the company for five years focusing on operations and growth.

“We are grateful to SeAH who was one of the first investors in SparkLabs Global Ventures, our global seed fund, and now the anchor investor along with Korea Development Bank/Multi-Asset in our new Series A fund for South Korea. We believe we have assembled the best team to service entrepreneurs in Korea since all of us have built companies from the ground up in Korea and the U.S.,” stated HanJoo Lee, co-founder of SparkLabs.

SeAH is a top 50 business group in South Korea and Korea Development Bank/Multi-Asset is subsidiary of Mirae Asset, which is the largest asset manager in South Korea with over US$100 billion assets under management.

Brian Kang and Chris Koh are joined by Venture Partners (part-time partners) Rob Das, Co-founder and former Chief Architect of Splunk, and John Suh, CEO of Legalzoom. Splunk is a $8 billion market cap company that Rob helped grow from concept to its IPO in 2012. John has served as CEO since 2007 to help grow Legalzoom into the leading provider of online legal document services in the U.S. that has serviced almost 4 million customers.

“We are excited to launch this new early-stage fund to help Korea’s rapidly growing startup ecosystem. I believe the venture capital business must evolve as the startup environment is changing fast in Korea. Finding companies of global capacity, generating rich deal flow, adding real values post investment are becoming more and more critical to the success of venture investments. Chris and I look forward to working with other investors to help nurture the next generation of impact entrepreneurs in South Korea,” said Brian Kang, Co-founder and Managing Partner of SparkLabs Ventures.

SparkLabs Ventures is also supported by a heavy hitting advisory board that includes former Congressman Mike Honda, who served in the U.S. Congress from 2001 to 2017 (represented Silicon Valley in the 17th congressional district from 2013 to 2017); David Lee, Co-founder and Managing Partner of Refactor Capital; and Nadiem Makarim, Co-founder and CEO of Go-Jek, which recently raised $1.2 billion from Tencent and others.

The fund will focus primarily on South Korea startups at their Series A or B rounds, and will not be limited to graduates of SparkLabs accelerator in Seoul. The fund will focus its investments on companies that have potential to expand abroad to different markets and have the ability to take advantage of the global reach of the SparkLabs’ network. A secondary target region is SE Asia, so the fund will be open to startups within this region who have global ambitions.

The popularity of organic light-emitting diode (OLED) TVs and smartphones has boosted not only the OLED display market but also the OLED encapsulation materials market. According to IHS Markit(Nasdaq: INFO),  the OLED encapsulation materials market is expected to grow 4.7 percent in 2017 compared to a year ago, to $117 million.

“The market is forecast to grow even faster as Chinese and South Korean panel makers have aggressively invested in new OLED fabs, resulting in the increase in OLED shipments in terms of area,” said Richard Son, senior analyst at IHS Markit. In particular, South Korean Chinese panel makers recently announced new OLED fab investment plans for not only Gen 6 but also Gen 8.5 and even for Gen 10.5.

As a result of the investment, the OLED encapsulation materials market is forecast to reach $232.5 million by 2021, growing at a compound annual growth rate of 16 percent from 2017.

OLED_encapsulation_materials_market_forecast

Unlike thin-film transistor liquid crystal display (TFT-LCD), OLED displays require encapsulation as the organic elements are vulnerable to moisture. The OLED encapsulation materials can be categorized into metal, frit glass, thin-film encapsulation (TFE) and hybrid.

The metal type is expected to lead the market in terms of revenue because it is mainly used for OLED TVs whose growth is fastest. However, with Chinese smartphone brands releasing a wide range of new products with OLED panels, demand for frit glass encapsulation materials, which are currently applied to smartphones with rigid-OLED displays, will remain steady, though losing its market share.

According to the AMOLED Encapsulation Materials Report 2017 by IHS Markit, in terms of revenue, metal type encapsulation is expected to account for 50 percent and the frit glass type to take 43 percent in 2017, and 67 percent and 23 percent in 2021, respectively.

OLED_encapsulation_market_share_forecast_by_technology

“Hybrid encapsulation, which combines TFE with a barrier film, has high production cost and its flexibility is limited, and thus demand for the hybrid type will not increase significantly,” Son said. “However, the latecomers are focusing on the hybrid encapsulation as it has a lower technological entry barrier compared to TFE, allowing them to succeed in mass production faster than when using TFE.”

From a mid- and long-term perspective, the hybrid encapsulation materials market will continue to grow for a while. TFE and the hybrid type are expected to take 6 percent and 1 percent of the encapsulation materials revenue market in 2017, respectively, but they will grow to reach 7 percent and 3.5 percent respectively in 2021.

The AMOLED Encapsulation Materials Report 2017 by IHS Markit provides information about the entire range of OLED encapsulation materials shipments by technology and application, including five-year forecast. Latest industry trends, including new technology development trends, are also updated.

Rechargeable batteries are essential for powering our personal electronic devices. To meet the novel functions of next-generation electronics, including foldable displays, flexible power sources are needed. However, conventional batteries are rigid and unable to adapt to the demands of flexible devices. Low-cost, rechargeable batteries containing naturally abundant elements, such as zinc, are appealing, but flexible batteries based on zinc require a different preparation method from conventional batteries.

In their article in Advanced Energy Materials, Xu Chen, Bin Liu, Cheng Zhong, and co-workers have developed a high-performance, flexible air electrode for the Zn–air battery by devising a simple fabrication technique.

The technique involves electrodeposition with fast heat treatment to grow ultrathin mesoporous Co3O4 layers on the surface of carbon fibers on a carbon cloth. These ultrathin Co3O4 layers have a maximum contact area on the conductive support, facilitating rapid electron transport and preventing the aggregation of the layers.

Benefiting from the high utilization degree of active materials and rapid charge transport, the mass activity for oxygen reduction and evolution reactions of the ultrathin electrode is more than 10 times higher than that of the carbon cloth loaded with commercial Co3O4 nanoparticles. The as-assembled flexible Zn–air battery based on the ultrathin electrode exhibits excellent rechargeability (≈1.03 V discharge voltage and ≈1.95 V charge voltage at 2 mA cm–2), with a high charge density of 546 Wh kg–1. It also has a high cycling stability, where no obvious loss occurred after 10 hours of galvanostatic discharge–charge testing or after 300 mechanical bending cycles.

The authors also integrated a flexible display into the device. Despite repeated bending and twisting, the device maintains its mechanical integrity and discharge performance. When the device is cut by scissors, there is no perceptible change in the display brightness, signaling safe and reliable operation if the device is damaged.

To find out more about this flexible battery, please visit the Advanced Energy Materials homepage.

Rudolph Technologies, Inc. (NYSE: RTEC) announced today that it has received an order for a JetStep G lithography system from a second customer in China for pilot line manufacturing of next-generation AMOLED (active-matrix organic light-emitting diode) displays.

The use of AMOLED displays in smartphones and wearables is growing rapidly because of their superior performance and form factor. Given the wide variety and rapid proliferation of consumer devices, an R&D or pilot line facility that can quickly and cost-effectively implement new processes allows manufacturers to bring new products to market faster. As these products continue to evolve, the need persists for low-power, low-cost, and conformity. Rudolph’s lithography solutions provide customers with the ability to develop these new processes with lower tooling costs and quicker product change-over.

Elvino da Silveira, vice president of marketing at Rudolph Technologies, said, “The AMOLED panel market is currently experiencing rapid growth, and in fact, UBI Research expects it to grow by close to 40 percent on an annual basis until 2020. We are seeing more and more companies enter this market by developing their own intellectual property, especially in China.”

“Customers continue to invest in Rudolph’s unique lithography solution for their R&D and pilot lines because it enables them to prove-out new processes more easily and at lower cost,” da Silveira continued. “The JetStep system is especially beneficial in pilot line environments where there is a high level of product change-over and pressure to minimize cost. A JetStep mask set, for example, is a fraction of the cost of a mask set for scanner-based photolithography tools, making it an ideal choice for new product development.”

The JetStep G lithography system addresses the AMOLED displays’ requirement for higher performance transistors by delivering finer resolution and tighter overlay. Additionally, the proprietary real-time magnification compensation and autofocus capabilities enable flexible substrate lithography. These capabilities are exactly what FPD manufacturers in China are looking for as they invest in capacity for next-generation AMOLED. Beyond the technology, Chinese manufacturers are looking for comprehensive and localized services. Rudolph is expanding capabilities in this area through the use of localized partnerships.

“With these technological advantages and local presence, we are poised to capture orders from additional China-based manufacturers,” da Silveira concluded.

As the global TV market continues to struggle with unit volume growth overall in 2017 — now projected to decline for the second year in a row — attention has turned to the most profitable market segments. This includes larger screen sizes and advanced technologies like OLED, quantum dots, 4K and HDR, each of which helps boost average selling prices and profits. In fact, OLED TV revenues are forecast to grow 71 percent year-over-year in 2017, while 4K TV revenues will increase 31 percent year-over-year, according to IHS Markit (Nasdaq: INFO). A number of brands have adopted OLED technology into their TV lineups in 2017, including Sony, joining LG Electronics, the primary promoter of OLED.

In 2016, the share of TV shipments at $1,000 and higher price points amounted to 5 percent of units, but more than 20 percent of dollars. Largely this is driven by the rapid share growth of 4K, especially at the largest screen sizes, where the retail premium for 4K has held remarkably steady without impacting average size growth.

Within the $1,000 and higher market segment, OLED TV share has grown significantly during the past eight quarters, from 2.4 percent in first quarter 2015 to 13.8 percent in first quarter 2017. Looking forward, IHS Markit is forecasting OLED TV shipments to grow from 723k units in 2016, to 6.6 million units in 2021. However, due to the very high average selling price of OLED, the unit share of the $1,000-plus market will increase to a peak of 59 percent in 2019, before declining as 8K LCD TVs begin shipping with very high prices as well.

The average selling price of a 4K OLED TV in 2017, forecast at $2,247,  is nearly 6 times greater than the average LCD TV, and three times greater when looking at just the 50-inch-plus and larger size category. However, the introduction of quantum dot enabled LCD TVs more directly competes with OLED TVs at the highest price points. Quantum dot LCD TVs are expected to account for 4 percent of LCD TV shipments in 2017, rising to 15 percent by 2021, and exceeding OLED TV shipments in the process. Samsung is the dominant brand in the quantum dot LCD TV category, accounting for 90 percent of shipments in first quarter 2017.

By 2020, 8K LCD TVs will have launched in all regions, primarily at 65-inch and 75-inch screen sizes. At the early introduction stages, 65-inch 8K LCD TVs will carry a 35 percent premium against 65-inch 4K OLED TVs, but gradually reduce as capacity rapidly increases in LCD fabs optimized for 65-inch-plus screen sizes.

BY PETE SINGER, Editor-in-Chief

Do you know what’s coming? The semiconductor industry is evolving rapidly, driven by new demands from an increasingly diverse array of applications, including the IoT, 5G telecommunication, autonomous driving, virtual and augmented reality, and artificial intelligence/deep learning. Solid State Technology will be conducting a new survey will take aim at understanding what this evolution means to the semicon-ductor manufacturing industry supply chain in terms of the technology that will be needed.

IoT alone is expected to drive not only a huge demand for sensors, but a far more sophisticated cloud computing infrastructure that will employ the most advanced logic and memory chips available, including 7 and 5nm logic devices and 3D NAND. The survey will provide answer to questions such as:

  • What new materials are going into volume production and what kind of challenges do they create in terms of availability, handling and disposal?
  • How are fabs dealing with more complex devices structures such as FinFETs and 3D NAND which can create new pressures on process control, yield, and economics?
  • EUV lithography is expected to be in volume production for the 5nm node, if not sooner. What new opportunities and challenges will this create in the supply chain for process equipment, materials and inspection tools?
  • 200mm fabs are seeing a resurgence, in part due to the booming market for IoT devices and sensors. How will this impact the leading edge?
  • What kind of new challenges and opportunities exist in heterogeneous integration and advanced packaging?

The survey will be conducted across the entire Solid State Technology audience, which includes more than 180,000 engineering and management professionals in 181 countries. The report will be compiled by Solid State Technology editors, who will add valuable insights and interpretations based on decades of experience.

Stay tuned for the survey – we welcome your input!

In the current, unprecedented phase of active matrix organic light emitting diode (AMOLED) panel factory build-out, flexible AMOLED capacity will expand from 1.5 million square meters to 20.1 million square meters between 2016 and 2020, at a compound annual growth rate of 91 percent. In 2016, flexible capacity, or factories with the ability to produce AMOLEDs on plastic substrates, only accounted for 28 percent of total capacity targeting mobile applications. This will increase to 80 percent by 2020 as almost every new Gen 6 fab and smaller factory built over the next four years will be flexible compatible, according to IHS Markit (Nasdaq: INFO).

AMOLED_capacity_targeting_mobile_applications_by_substrate_type

According to the Display Supply Demand & Equipment Tracker by IHS Markit, between 2016 and 2020, China, Japan and South Korea will build the equivalent of 46 new flexible AMOLED fabs, whose monthly capacity reaches 30,000 substrates, each. These fabs will add 18.6 million square meters of new plastic substrate production capability, more than 13 times the industry’s current level.

“All of the new capacity will facilitate a rapid increase in flexible AMOLED panel adoption in smartphones,” said Charles Annis, senior director at IHS Markit. “Nevertheless, as so much new flexible capacity is being added, it is starting to raise concerns that the market will not be able to absorb all of the potential output.”

IHS Markit forecasts that the tight AMOLED panel supply in 2016 will continually give way to a growing capacity-based glut. The supply is predicted to exceed demand by more than 45 percent in 2020, when 40 percent of smartphones will adopt AMOLED panels.

“AMOLED displays will offer excellent image quality and form factor advantages in high-end phones. Despite excessive capacity availability, the challenge to faster adoption will be costs,” Annis said. High manufacturing costs for most makers will keep average rigid AMOLED panel prices 40 percent above equivalent LCD panels, while flexible AMOLED panel prices will remain 100 percent higher. “Smartphone makers, targeting mid and low-end market segments, may want to buy flexible AMOLED panels, but are likely to be restricted by lingering high prices.”

To absorb all the new capacity in the pipeline, flexible AMOLED panels will need to expand the market beyond smartphones to tablet PCs, notebooks and new form factors enabled by foldable displays. Ultimately, the rapid growth of flexible AMOLED capacity and the resulting increase in panel production will help to lower costs, increase yields and improve quality. In the long-run, this will spur further adoption into more applications; however, to get there, the industry may first need to cycle through a difficult period of digesting the 46 new flexible fabs now being built.

Imagine slipping into a jacket, shirt or skirt that powers your cell phone, fitness tracker and other personal electronic devices as you walk, wave and even when you are sitting.

A new, ultrathin energy harvesting system developed at Vanderbilt University’s Nanomaterials and Energy Devices Laboratory has the potential to do just that. Based on battery technology and made from layers of black phosphorus that are only a few atoms thick, the new device generates small amounts of electricity when it is bent or pressed even at the extremely low frequencies characteristic of human motion.

“In the future, I expect that we will all become charging depots for our personal devices by pulling energy directly from our motions and the environment,” said Assistant Professor of Mechanical Engineering Cary Pint, who directed the research.

The new energy harvesting system is described in a paper titled “Ultralow Frequency Electrochemical Mechanical Strain Energy Harvester using 2D Black Phosphorus Nanosheets” published Jun.21 online by the journal ACS Energy Letters.

“This is timely and exciting research given the growth of wearable devices such as exoskeletons and smart clothing, which could potentially benefit from Dr. Pint’s advances in materials and energy harvesting,” observed Karl Zelik, assistant professor of mechanical and biomedical engineering at Vanderbilt, an expert on the biomechanics of locomotion who did not participate in the device’s development.

Currently, there is a tremendous amount of research aimed at discovering effective ways to tap ambient energy sources. These include mechanical devices designed to extract energy from vibrations and deformations; thermal devices aimed at pulling energy from temperature variations; radiant energy devices that capture energy from light, radio waves and other forms of radiation; and, electrochemical devices that tap biochemical reactions.

“Compared to the other approaches designed to harvest energy from human motion, our method has two fundamental advantages,” said Pint. “The materials are atomically thin and small enough to be impregnated into textiles without affecting the fabric’s look or feel and it can extract energy from movements that are slower than 10 Hertz–10 cycles per second–over the whole low-frequency window of movements corresponding to human motion.”

Doctoral students Nitin Muralidharan and Mengya Li co-led the effort to make and test the devices. “When you look at Usain Bolt, you see the fastest man on Earth. When I look at him, I see a machine working at 5 Hertz,” said Muralidharan.

Extracting usable energy from such low frequency motion has proven to be extremely challenging. For example, a number of research groups are developing energy harvesters based on piezoelectric materials that convert mechanical strain into electricity. However, these materials often work best at frequencies of more than 100 Hertz. This means that they don’t work for more than a tiny fraction of any human movement so they achieve limited efficiencies of less than 5-10 percent even under optimal conditions.

“Our harvester is calculated to operate at over 25 percent efficiency in an ideal device configuration, and most importantly harvest energy through the whole duration of even slow human motions, such as sitting or standing,” Pint said.

The Vanderbilt lab’s ultrathin energy harvester is based on the group’s research on advanced battery systems. Over the past 3 years, the team has explored the fundamental response of battery materials to bending and stretching. They were the first to demonstrate experimentally that the operating voltage changes when battery materials are placed under stress. Under tension, the voltage rises and under compression, it drops.

The team collaborated with Greg Walker, associate professor of mechanical engineering, who used computer models to validate these observations for lithium battery materials. Results of the study were published Jun. 27 in the journal ACS Nano in an article titled “The MechanoChemistry of Lithium Battery Electrodes.”

These observations led Pint’s team to reconstruct the battery with both positive and negative electrodes made from the same material. Although this prevents the device from storing energy, it allows it to fully exploit the voltage changes caused by bending and twisting and so produce significant amounts of electrical current in response to human motions.

The lab’s initial studies were published in 2016. They were further inspired by a parallel breakthrough by a group at Massachusetts Institute of Technology who produced a postage-stamp-sized device out of silicon and lithium that harvested energy via the effect Pint and his team were investigating.

In response, the Vanderbilt researchers decided to go as thin as possible by using black phosphorus nanosheets: A material has become the latest darling of the 2D materials research community because of its attractive electrical, optical and electrochemical properties.

Because the basic building blocks of the harvester are about 1/5000th the thickness of a human hair, the engineers can make their devices as thin or as thick as needed for specific applications. They have found that bending their prototype devices produces as much as 40 microwatts per square foot and can sustain current generation over the full duration of movements as slow as 0.01 Hertz, one cycle every 100 seconds.

The researchers acknowledge that one of the challenges they face is the relatively low voltage that their device produces. It’s in the millivolt range. However, they are applying their fundamental insights of the process to step up the voltage. They are also exploring the design of electrical components, like LCD displays, that operate at lower than normal voltages.

“One of the peer reviewers for our paper raised the question of safety,” Pint said. “That isn’t a problem here. Batteries usually catch on fire when the positive and negative electrodes are shorted, which ignites the electrolyte. Because our harvester has two identical electrodes, shorting it will do nothing more than inhibit the device from harvesting energy. It is true that our prototype will catch on fire if you put it under a blowtorch but we can eliminate even this concern by using a solid-state electrolyte.”

One of the more futuristic applications of this technology might be electrified clothing. It could power clothes impregnated with liquid crystal displays that allow wearers to change colors and patterns with a swipe on their smartphone. “We are already measuring performance within the ballpark for the power requirement for a medium-sized low-power LCD display when scaling the performance to thickness and areas of the clothes we wear.” Pint said.

Pint also believes there are potential applications for their device beyond power systems. “When incorporated into clothing, our device can translate human motion into an electrical signal with high sensitivity that could provide a historical record of our movements. Or clothes that track our motions in three dimensions could be integrated with virtual reality technology. There are many directions that this could go.”