Category Archives: Displays

The growing popularity of smartwatches, fitness monitors and other wearable applications is driving up shipments of the displays used in these devices, from 34 million units in 2015 to 39 million in 2016. Nearly six out of 10 displays used in wearable devices in 2015 were active-matrix organic light-emitting diode (AMOLED) panels used in smartwatches, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight.

“Smartwatch manufacturers are increasingly turning to AMOLED displays because they are thinner, lighter, have high color-performance and consume less power than other types of displays,” said Jerry Kang, principal analyst for IHS Technology. “This trend will continue in 2016, since flexible AMOLED display free-form design process enables narrower form factors and even folding bezels.”

Apple, Samsung Electronics, LG Electronics, and Microsoft have all adopted flexible AMOLED displays for their smartwatches. Supported by this widespread adoption by leading manufacturers, unit shipments of flexible AMOLED displays for smartwatches are expected to increase from 23 million units in 2016 to 80 million in 2024.

Smartwatches are expected to continue to lead the wearable display market in the coming years. Unit shipments are forecast to grow at a compound annual growth rate of 22 percent from 2015 and reach 118 million units in 2024, according to the IHS Wearable Display Market & Technology ReportEven with this growth, total unit shipments of smartwatch displays will only equal 5 percent of smartphone display shipments in 2024.

Wearable_Display_Shipments

Chemists and polymer scientists collaborating at the University of Massachusetts Amherst reported this week that they have for the first time identified an unexpected property in an organic semiconductor molecule that could lead to more efficient and cost-effective materials for use in cell phone and laptop displays, for example, and in opto-electronic devices such as lasers, light-emitting diodes and fiber optic communications.

Physical chemist Michael Barnes and polymer scientist Alejandro Briseño, with doctoral students Sarah Marques, Hilary Thompson, Nicholas Colella and postdoctoral researcher Joelle Labastide, discovered the property, directional intrinsic charge separation, in crystalline nanowires of an organic semiconductor known as 7,8,15,16-tetraazaterrylene (TAT).

A new paper from UMass Amherst describes a structure that will make it easier to use a certain molecule for new applications, for example in devices that use polarized light input for optical switching, by exploiting its directionality. Inset shows a structural schematic of the TAT crystal packing geometry and direction of charge separation. Credit: UMass Amherst/Mike Barnes

A new paper from UMass Amherst describes a structure that will make it easier to use a certain molecule for new applications, for example in devices that use polarized light input for optical switching, by exploiting its directionality. Inset shows a structural schematic of the TAT crystal packing geometry and direction of charge separation. Credit: UMass Amherst/Mike Barnes

The researchers saw not only efficient separation of charges in TAT, but a very specific directionality that Barnes says “is quite useful. It adds control, so we’re not at the mercy of random movement, which is inefficient. Our paper describes an aspect of the nanoscopic physics within individual crystals, a structure that will make it easier to use this molecule for new applications such as in devices that use polarized light input for optical switching. We and others will immediately exploit this directionality.”

He adds, “Observing the intrinsic charge separation doesn’t happen in polymers, so far as we know it only happens in this family of small organic molecule crystalline assemblies or nanowires. In terms of application we are now exploring ways to arrange the crystals in a uniform pattern and from there we can turn things on or off depending on optical polarization, for example.”

However, the UMass Amherst team believes the property is not an oddity unique to this material, but that several materials potentially share it, making the discoveries in TAT interesting to a wide variety of researchers, Barnes says. Similar kinds of observations have been noted in pentacene crystals, he notes, which show something similar but without directionality. In this work supported by the U.S. Department of Energy and UMass Amherst’s Center for Hierarchical Manufacturing, they propose that the effect comes from a charge-transfer interaction in the molecule’s charge-conducing nanowires that can be programmed.

In the conventional view of harvesting solar energy with organic or carbon-based organic materials, the chemist explains, scientists understood that the organic active layers at work in devices absorb light, which leads to an excited state known as an exciton. In this mechanism, the exciton migrates to an interface boundary where it separates into a positive and negative charge, freeing the voltage to be used as power. “In this view, you hope that the light is well absorbed so the transfer is efficient,” he says.

In earlier work, Barnes, Briseño and others at UMass Amherst worked to control the domain size of materials to match what was believed to be the distance an exciton can travel in the time it takes to radiate, he adds. “All of this premised on idea that the mechanism for charge separation is extrinsic, that an external driving force separates the charges,” he notes. The goal had been to remove the need for that interface.”

Most recently, Briseño and colleagues reached a point in synthesizing crystals where their polymer-based devices were not performing the way they wanted, he relates. Briseño asked Barnes and colleagues to use their special measurement instrumentation to investigate. Barnes and colleagues found a structural defect that Briseño could fix. “We provided some diagnostics to him to improve their crystal growth,” Barnes says.

“From this, we noticed clues that there were some very interesting things going on, which led us to the discovery,” Barnes adds. “It’s fun when science works that way. It was a very nice mutually beneficial relationship.”

“What Nature brought us was something really much richer and more interesting than anything we could have anticipated. We thought it was going to be qualitatively similar to previous observations, perhaps different in quantitative particulars, but the real story is far more interesting. In this material, they found the way it packs crystals gives rise to its own separation, an intrinsic property of the crystalline material.”

SEMI today announced the “Call for Papers” for technical sessions and presentations for SEMICON Europa 2016 which takes place 25-27 October in Grenoble, France.

SEMICON Europa 2016 will feature more than 100 hours of technical sessions and presentations focused on critical industry topics that are shaping the design and manufacturing of semiconductors, MEMS, printed and flexible electronics, and other related technologies.  Abstracts for presentations are now being accepted for:

  • Advanced Packaging Conference: “The Balancing Act between Consumer and Harsh Environment Packaging”
  • Power Electronics Conference: “The Power Awakens”
  • 2016FLEX Europe: “Silicon Electronics + Flexible Systems Enabling New Markets”

The SEMICON Europa 2016 abstract submission deadline is 29 April.  Prospective presenters are invited to submit abstracts (1,000-2,000 characters). Material must be original, non-commercial and non-published. Abstracts must clearly detail the nature, scope, content, organization, key points, and significance of the proposed presentation.  Visit www.semiconeuropa.org or contact Christina Fritsch, SEMI Europe, at Tel: +49 30 303080770 or email [email protected].

Co-located and leveraging SEMICON Europa 2016, 2016FLEX Europe(formerly known as PE Europe)will also take place in Grenoble from 25-27 October.

SEMICON Europa and 2016FLEX Europe (now powered by SEMI’s Strategic Association Partner FlexTech) will attract over 5,500 attendees involved in the microelectronics supply chain, from equipment and material suppliers, IC manufacturers, system integrators to end users. Special programs this year focus on advanced and smart manufacturing (Industry 4.0), power electronics, imaging, electronics and materials for the medical and automotive applications, creating an opportunity to explore applications and manufacturing solutions for flexible, printed and hybrid electronics.

Applied Materials, Inc. today announced that Dr. Robert Visser has received a 2016 Special Recognition Award from the Society of Information Display, an industry organization comprised of the top scientists, engineers, corporate researchers and business people of the display field. The award is for his “pioneering research and commercialization of new display technologies related to OLEDs*, LCD* materials and barrier films, including encapsulation technologies for OLED and flexible displays.” Dr. Visser is senior director of advanced chemistry and materials for the Advanced Technology Group at Applied Materials, where he is responsible for creating business opportunities in new and adjacent markets related to displays and roll-to-roll barrier films, as well as developing novel chemistries for semiconductor manufacturing. 

“Robert contributed to turning the concept of flexible displays into a reality by helping establish the principles for successful encapsulation of highly sensitive devices, such as OLED displays,” said Dr. Om Nalamasu, senior vice president and CTO of Applied Materials. “Robert continues to be a critical source of insight and expertise on display materials, and I congratulate him on this well-deserved award.”

Dr. Visser’s work in the display industry spans more than three decades. Most recently at Applied, he helped the display group develop new thin-film encapsulation systems that enable the volume production of high-resolution, thin and lightweight flexible OLED displays for mobile products and TVs. He also works closely with the Roll-to-Roll Coating Products Division to design new equipment for depositing barrier films that can be used throughout the world for a wide variety of flexible packaging and labeling applications. 

Prior to joining Applied, Dr. Visser was CTO of Vitex Systems, where he led a multi-disciplinary team to demonstrate and refine multi-layer barrier technology for use in OLED displays. This work eventually became the basis on which many of today’s plastic, curved OLED displays are built. Dr. Visser began his career at Philips Research, where he led several research teams and helped create the PolyLED business serving as the group’s CEO and CTO. Under his leadership, the group launched one of the first OLED displays on the market in 2002. Also during this time he worked with other researchers and members of academia to make significant improvements in performance and yield of early OLED display manufacturing.

Dr. Visser holds a master’s degree in theoretical organic chemistry and physics, and a Ph.D. in physical and organic chemistry, both from Leiden University, Netherlands. He has numerous patents and publications to his name.

Global sales of smartphones to end users totaled 403 million units in the fourth quarter of 2015, a 9.7 percent increase over the same period in 2014, according to Gartner, Inc. However, this was their slowest growth rate since 2008. In 2015 as a whole, smartphone sales reached 1.4 billion units, an increase of 14.4 percent from 2014.

“Low-cost smartphones in emerging markets, and strong demand for premium smartphones, continued to be the driving factors,” said Anshul Gupta, research director at Gartner. “An aggressive pricing from local and Chinese brands in the midrange and entry-level segments of emerging markets led to consumers upgrading more quickly to affordable smartphones.”

Mr. Gupta said that 85 percent of users in the emerging Asia/Pacific market are replacing their current midrange phone with the same category of phone. In addition, currency devaluations against the U.S. dollar in many emerging markets are putting further margin pressure on many vendors that import devices. Current market conditions are prompting some vendors to consider setting up manufacturing operations in India and Indonesia to avoid being hit by future unfavorable currency devaluations and high import taxes.

In the fourth quarter of 2015, Samsung and Huawei were the only two top-five smartphone vendors to increase their sales to end users (see Table 1). Apple suffered its first decline in sales of smartphones — iPhone sales were down 4.4 percent.

Table 1

Worldwide Smartphone Sales to End Users by Vendor in 4Q15 (Thousands of Units)

Company

4Q15

Units

4Q15 Market Share (%)

4Q14

Units

4Q14 Market Share (%)
Samsung

83,437.7

20.7

73,031.5

19.9
Apple

71,525.9

17.7

74,831.7

20.4
Huawei

32,116.5

8.0

21,038.1

5.7
Lenovo*

20,014.7

5.0

24,299.9

6.6
Xiaomi

18,216.6

4.5

18,581.6

5.1
Others

177,798.0

44.1

155,551.6

42.3
Total

403,109.4

100.0

367,334.4

100.0

*The figures for Lenovo include sales of mobile phones by both Lenovo and Motorola

Source: Gartner (February 2016) 

Although Samsung was the No.1 vendor, Gartner analysts said the company faces challenges. “For Samsung to stop falling sales of premium smartphones, it needs to introduce new flagship smartphones that can compete with iPhones and stop the churn to iOS devices,” said Mr. Gupta.

With an increase in sales of 53 percent in the fourth quarter of 2015, Huawei achieved the best performance year over year. Huawei’s increased brand visibility overseas, and its decision to sell almost only smartphones, gave it a higher average selling price in 2015.

For total sales of smartphones in 2015, Samsung maintained the No. 1 position, but its market share declined by 2.2 percentage points (see Table 2). In 2015, Apple sold 225.9 million iPhones, to achieve a market share of almost 16 percent. Huawei’s smartphone sales approached 104 million units, up 53 percent year over year.

Table 2

Worldwide Smartphone Sales to End Users by Vendor in 2015 (Thousands of Units)

Company

2015

Units

2015 Market Share (%)

2014

Units

2014 Market Share (%)
Samsung

320,219.7

22.5

307,596.9

24.7
Apple

225,850.6

15.9

191,425.8

15.4
Huawei

104,094.7

7.3

68,080.7

5.5
Lenovo*

72,748.2

5.1

81,415.8

6.5
Xiaomi

65,618.6

4.6

56,529.3

4.5
Others

635,368.5

44.6

539,691.3

43.4
Total

1,423,900.3

100.0

1,244,739.8

100.0

*The figures for Lenovo include sales of mobile phones by both Lenovo and Motorola

Source: Gartner (February 2016) 

In terms of smartphone operating system (OS) market, Android increased 16.6 percent in the fourth quarter of 2015, to account for 80.7 percent of the global total (see Table 3). “Android benefited from continued demand for affordable smartphones and from the slowdown of iOS units in the premium market in the fourth quarter of 2015,” said Roberta Cozza, research director at Gartner. In the premium segment, despite Apple’s slower year-over-year fourth-quarter sales, Apple narrowed the market share gap with Samsung in 2015 as a whole. 

Table 3

Worldwide Smartphone Sales to End Users by Operating System in 4Q15 (Thousands of Units)

Operating System

4Q15

Units

4Q15 Market Share (%)

4Q14

Units

4Q14 Market Share (%)
Android

325,394.4

80.7

279,057.5

76.0
iOS

71,525.9

17.7

74,831.7

20.4
Windows

4,395.0

1.1

10,424.5

2.8
Blackberry

906.9

0.2

1,733.9

0.5
Others

887.3

0.2

1,286.9

0.4
Total

403,109.4

100.0

367,334.4

100.0

Source: Gartner (February 2016) 

Neon shortage coming


February 18, 2016

The current Neon demand is growing in “stealth mode” – hidden from the layman’s view because of significant factors only analysts fully versed in lithography, OLED/FPD and semiconductor device trends would catch. The traditional method of using historical data to predict future Neon demand will grossly underestimate future usage.

“Those who are basing their thinking on projections of historical Neon growth are in for a big surprise,” said TECHCET’s President/CEO, Lita Shon-Roy.   “Even with the recovery of the Neon supply chain, Neon conservation actions, and new sources in China, we predict that Neon demand will grow faster than Neon supply,” she added.

The largest and most rapidly growing Neon demand drivers are Lasik, OLED/FPD (displays) and DUV lithography. However, Neon gas consumed by DUV excimer laser gases is growing at a faster pace and represents more than 90% of world’s Neon consumption.

Semiconductor lithographic use of Neon is increasing more rapidly than expected for several reasons including the delay of EUVL while demand for finer line width patterning is increasing. In addition, new consumer related markets drive increased usage of legacy device processing. Each increase in the number of lithographic steps increases the need for more DUV lithography tools, and drives up the volume demand for Neon. This is true for V-NAND process flows, as well as DRAM and Logic devices dependent on multi-patterning.

Currently, the installed base of DUV lithography tools is ~ 4,400. In contrast, there have only been a dozen or so EUVL tools shipped through the end of 2015.

“The continued growth of DUV tools will push up demand for NEON beyond which supply can support,” cautioned Shon-Roy.

More details can be found from TECHCET’s latest Critical Materials Report on NEON Supply & Demand. Information will also be presented at the CMC Conference, scheduled for May 5-6, in Hillsboro, Oregon – this is the open forum portion of the Critical Materials Council meetings. For more information go to http://techcet.com/product/neon-a-supply-alert-report/ For more information on the CMC Conference please go to www.cmcfabs.org/seminars/

CMC Fabs is a membership based group that actively works to identify issues surrounding the supply, availability, and accessibility of semiconductor process materials, current and emerging, “Critical Materials.” CMC Fabs is managed by TECHCET CA LLC, a firm focused on Process Materials Supply Chains, Electronic Materials Technology Trends, and Materials Market Analysis for the Semiconductor, Display, Solar/PV, and LED Industries. The Company has been responsible for producing the SEMATECH Critical Material Reports since 2000.

With the growing popularity of the Samsung Galaxy Edge series and the Apple Watch, display manufacturers are expanding their production capacity of flexible active-matrix organic light-emitting diode (AMOLED) displays. While comprising just 2 percent of all AMOLED panel shipments in 2014, the share of flexible AMOLED panels rose to 20 percent of the total AMOLED display market in 2015, reaching 57 million units, according to IHS Inc., a global source of critical informational and insight.

The unit-shipment share of flexible AMOLED is expected to grow to 40 percent of total AMOLED panel shipments in 2020. Rigid AMOLED panel shipments, by comparison grew 30 percent to reach 233 million units in 2015. Production capacity for flexible AMOLED panels is expected to exceed 1.5 million square meters (24 percent of total AMOLED display production capacity area) in 2016,

“As the demand for flexible AMOLED rises dramatically, display manufacturers are aggressively investing in flexible AMOLED, including the latest foldable and rollable displays,” said Jerry Kang, principal analyst of display research for IHS Technology. “In fact, the growth rate for flexible AMOLED panels is expected to be much higher than for rigid AMOLED panels beginning in 2016.

According to the IHS OLED Technology, Strategy & Market Report, Samsung Display lowered its manufacturing cost for rigid AMOLED panels, to compete with low temperature polysilicon (LTPS) liquid crystal displays (LCDs). Samsung Display’s primacy in the rigid AMOLED market, is now leading other panel makers to skip production of rigid AMOLED displays entirely and proceed directly to flexible AMOLED production.

“Manufacturers feel it’s already too late to compete in the rigid AMOLED market, where Samsung Display is already so far ahead,” said Kang. “Furthermore, a growing number of smartphone manufacturers, including Apple, are looking to thinner and lighter flexible AMOLED displays to differentiate their products, which is leading even more panel makers to rapidly shift their business focus to flexible AMOLED.”

AMOLED_Production_Chart

Shipments of organic light-emitting materials used to produce organic light-emitting diode (OLED) displays grew 12 percent year over year in 2015, reaching 26,000 tons. With the rapid growth of white OLED (WOLED) TV display shipments, shipments of organic light-emitting materials are expected to reach 100,000 tons in 2018, according to IHS Inc. (NYSE: IHS), a global source of critical information and insight. Revenues from organic materials used to produce OLED displays also grew 12 percent year over year, reaching $465 million in 2015. Revenue is expected to amount to $1.8 billion in 2018.

“The market for small and medium OLED displays is stable, and OLED TV shipments are increasing, which is supporting OLED light-emitting materials market growth,” said Kihyun Kim, senior analyst for chemical materials research at IHS Technology.  “Shipments of organic light-emitting materials for WOLED are expected to increase along with WOLED TV shipments, as more manufacturers are planning to adopt the technology. WOLED materials are expected to outstrip fine-metal-mask red-green-blue (FMM RGB) materials in 2017 for the first time.”

Organic light-emitting materials used in the FMM RGB technology, mostly used to produce smartphone displays, dominated the OLED materials market in 2015, with an 82 percent share. WOLED materials, mainly used for TVs, will account for 51 percent of the total OLED materials market in 2017 and 55 percent in 2018, in terms of shipments.

Revenue from WOLED materials, which made up 31 percent of the market in 2015, will account for 55 percent of the total organic light-emitting materials used to produce OLED displays in 2016. The growth in revenue is faster than that in shipments, because WOLED materials are more expensive than FMM RGB materials, because they haven’t yet reached an economy of scale.

OLED_Chemicals_Chart

Veeco Instruments Inc. announced today the launch of the new TurboDisc K475i Arsenic Phosphide (As/P) Metal Organic Chemical Vapor Deposition (MOCVD) System for the production of red, orange, yellow (R/O/Y) light emitting diodes (LEDs), as well as multi-junction III-V solar cells, laser diodes and transistors.

“Veeco continues to drive innovation with MOCVD technology that enables us to lower manufacturing costs and increase production with systems that are reliable, flexible and easy to use,” said Shuangxiang Zhang, General Manager of Yangzhou Changelight Co., Ltd.

According to research firm Strategies Unlimited, R/O/Y LED demand is expected to grow at a 10 percent compound annual rate through 2023. This demand for red, orange and yellow LEDs is being driven by signage, automotive, display and general lighting applications, as well as the emergence of new applications such as wearable smart devices.

Incorporating proprietary TurboDisc and Uniform FlowFlange MOCVD technologies, the new K475i system enables Veeco customers to reduce LED cost per wafer by up to 20 percent compared to alternative systems through higher productivity, best-in-class yields and reduced operating expenses.

Veeco’s proprietary Uniform FlowFlange technology produces films with very high uniformity and improved within-wafer and wafer-to-wafer repeatability resulting in the industry’s lowest cost of ownership. This patented technology provides ease-of-tuning for fast process optimization and fast tool recovery time after maintenance enabling the highest productivity for applications such as lighting, display, solar, laser diodes, pseudomorphic high electron mobility transistors (pHEMTs) and heterojunction bipolar transistors (HBTs).

Graphene, the two-dimensional powerhouse, packs extreme durability, electrical conductivity, and transparency into a one-atom-thick sheet of carbon. Despite being heralded as a breakthrough “wonder material,” graphene has been slow to leap into commercial and industrial products and processes.

Now, scientists have developed a simple and powerful method for creating resilient, customized, and high-performing graphene: layering it on top of common glass. This scalable and inexpensive process helps pave the way for a new class of microelectronic and optoelectronic devices–everything from efficient solar cells to touch screens.

The collaboration–led by scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory, Stony Brook University (SBU), and the Colleges of Nanoscale Science and Engineering at SUNY Polytechnic Institute–published their results February 12, 2016, in the journal Scientific Reports.

“We believe that this work could significantly advance the development of truly scalable graphene technologies,” said study coauthor Matthew Eisaman, a physicist at Brookhaven Lab and professor at SBU.

The scientists built the proof-of-concept graphene devices on substrates made of soda-lime glass–the most common glass found in windows, bottles, and many other products. In an unexpected twist, the sodium atoms in the glass had a powerful effect on the electronic properties of the graphene.

“The sodium inside the soda-lime glass creates high electron density in the graphene, which is essential to many processes and has been challenging to achieve,” said coauthor Nanditha Dissanayake of Voxtel, Inc., but formerly of Brookhaven Lab. “We actually discovered this efficient and robust solution during the pursuit of something a bit more complex. Such surprises are part of the beauty of science.”

Crucially, the effect remained strong even when the devices were exposed to air for several weeks–a clear improvement over competing techniques.

The experimental work was done primarily at Brookhaven’s Sustainable Energy Technologies Department and the Center for Functional Nanomaterials (CFN), which is a DOE Office of Science User Facility.

The graphene tweaks in question revolve around a process called doping, where the electronic properties are optimized for use in devices. This adjustment involves increasing either the number of electrons or the electron-free “holes” in a material to strike the perfect balance for different applications. For successful real-world devices, it is also very important that the local number of electrons transferred to the graphene does not degrade over time.

“The graphene doping process typically involves the introduction of external chemicals, which not only increases complexity, but it can also make the material more vulnerable to degradation,” Eisaman said. “Fortunately, we found a shortcut that overcame those obstacles.”

The team initially set out to optimize a solar cell containing graphene stacked on a high-performance copper indium gallium diselenide (CIGS) semiconductor, which in turn was stacked on an industrial soda-lime glass substrate.

The scientists then conducted preliminary tests of the novel system to provide a baseline for testing the effects of subsequent doping. But these tests exposed something strange: the graphene was already optimally doped without the introduction of any additional chemicals.

“To our surprise, the graphene and CIGS layers already formed a good solar cell junction!” Dissanayake said. “After much investigation, and the later isolation of graphene on the glass, we discovered that the sodium in the substrate automatically created high electron density within our multi-layered graphene.”

Pinpointing the mechanism by which sodium acts as a dopant involved a painstaking exploration of the system and its performance under different conditions, including making devices and measuring the doping strength on a wide range of substrates, both with and without sodium.

“Developing and characterizing the devices required complex nanofabrication, delicate transfer of the atomically thin graphene onto rough substrates, detailed structural and electro-optical characterization, and also the ability to grow the CIGS semiconductor,” Dissanayake said. “Fortunately, we had both the expertise and state-of-the-art instrumentation on hand to meet all those challenges, as well as generous funding.”

The bulk of the experimental work was conducted at Brookhaven Lab using techniques developed in-house, including advanced lithography. For the high-resolution electron microscopy measurements, CFN staff scientists and study coauthors Kim Kisslinger and Lihua Zhang lent their expertise. Coauthors Harry Efstathiadis and Daniel Dwyer–both at the College of Nanoscale Science and Engineering at SUNY Polytechnic Institute–led the effort to grow and characterize the high-quality CIGS films.

“Now that we have demonstrated the basic concept, we want to focus next on demonstrating fine control over the doping strength and spatial patterning,” Eisaman said.

The scientists now need to probe more deeply into the fundamentals of the doping mechanism and more carefully study material’s resilience during exposure to real-world operating conditions. The initial results, however, suggest that the glass-graphene method is much more resistant to degradation than many other doping techniques.

“The potential applications for graphene touch many parts of everyone’s daily life, from consumer electronics to energy technologies,” Eisaman said. “It’s too early to tell exactly what impact our results will have, but this is an important step toward possibly making some of these applications truly affordable and scalable.”

For example, graphene’s high conductivity and transparency make it a very promising candidate as a transparent, conductive electrode to replace the relatively brittle and expensive indium tin oxide (ITO) in applications such as solar cells, organic light emitting diodes (OLEDs), flat panel displays, and touch screens. In order to replace ITO, scalable and low-cost methods must be developed to control graphene’s resistance to the flow of electrical current by controlling the doping strength. This new glass-graphene system could rise to that challenge, the researchers say.