Category Archives: Touch Technologies

The capacitive touch controller IC market is predicted to reach about $2.8 billion in 2017, an increase of nearly 50 percent from $1.9 billion in 2013, according to a new report from IHS Technology.

The controller IC market used in capacitive touch panels is likely to grow at a compound annual growth rate (CAGR) of 10.6 percent from 2013 to 2017 as the application of touch functions are expanded to various products, the report says.

“The touch controller IC price is expected to drop as competition gets fierce in the market, but the capacitive touch controller IC market is likely to maintain its positive growth trend for now,” said Seung-kyu Richard Son, senior analyst at IHS Technology. “Touch solutions that can stimulate consumers’ emotions should emerge steadily in order for the market to continue to grow.”

The touch controller IC, a key component that determines the performance of touch panels, is a non-memory semiconductor that transforms analogue signals into digital signals. This occurs when a user touches the screen on a device.

Capacitive touch technology, the mainstream in today’s touch panel market, is leading the growth in the touch panel industry. Over the past eight years, it has steadily advanced in many areas, including structures, materials and processes.

The report noted that smartphones and tablet PCs have accounted for the majority of the capacitive touch-panel demand market. But towards the end of 2012, the application of touch panels have been expanded to other applications, including notebook PCs and monitors. Along with this, touch controller ICs have become more important.

Up until 2011, US companies — including Atmel, Synaptics, Cypress and Broadcom — had dominated the capacitive touch controller IC market. But as the demand for smartphones and tablet PCs soared, Asian companies, including Melfas from South Korea, and FocalTech, Goodix and Mstar from China and Taiwan, are actively entering the touch controller IC market with enhanced skills and price competitiveness, the report says.

More notably, touch controller IC companies from China and Taiwan are rapidly growing on account of their low-priced products as well as having better relations with local smartphone and tablet PC makers. Although there are clear technological gaps between leading Western companies and the Chinese-Taiwanese touch controller IC suppliers, the gap has narrowed as latecomers continue their investments in mergers and acquisitions and R&D.

“The growth in Chinese-Taiwanese companies has resulted in a fall in supply prices for touch controller ICs, which is having a positive impact on manufacturers,” Mr. Son said. However, an excessive drop in prices can lead to lower profits for some companies and, in the end, will curb new investments.”

These findings are available in the report, “Touch Controller IC Market & Development Trend Report,” from IHS Technology.

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Renesas Electronics America Inc., a supplier of advanced semiconductor solutions, today announced development of innovative new intellectual property (IP) that implements capacitive-touch sensing technology ideal for home appliances and healthcare equipment. The IP achieves high-touch sensitivity five times superior compared to that of Renesas’ R8C/3xT microcontrollers (MCUs), as well as high-noise immunity allowing the technology to pass strict noise tests. Furthermore, for the first time, Renesas IP supports the mutual-capacitance method which is more reliable and versatile than the conventional self-capacitance method.

In the human machine interface (HMI) field for electric and electronic equipment, touch-key manipulation interfaces are the subject of increasing attention. Capacitive-touch panels are being rapidly adopted because touch-key operation can easily improve reliability in product design and enhance the end-user experience. In fact, system manufacturers are now developing new touch panels with a curved surface, instead of the traditional planar surfaces that have been mainstream until now. Looking ahead, touch-panel technologies with even better sensitivity and noise resistance will become highly demanded for a wide range of applications.

Renesas helped to drive adoption of touch-key manipulation systems in October 2009 when it launched its R8C/3xT series of MCUs supporting capacitive-touch interfaces. Renesas expects strong growth in the market for touch-key systems and, by leveraging innovative technologies like its newest IP, the company intends to be a key player with technology and products supporting HMI applications.

As smart materials become one of the fastest growing areas of materials technology, SABIC and Cima NanoTech, a Singapore and US-based company, have announced the joint development of a plastics industry first: a transparent conductive polycarbonate film that has the potential to revolutionize the materials used in consumer electronics, household goods, automotive, architecture and healthcare.

Related news: Non-ITO film to make up 34% of transparent conductive film market in 2017

The new material, designed to provide “next generation” functionality, has the potential to further enhance performance, enable new innovative applications and open doors for new product designs, Ernesto Occhiello, SABIC Executive Vice President, Technology and Innovation, explained. This could translate into faster response touch screens for consumer electronics, transparent “no-line” anti-fogging capabilities for automotive windows, better EMI shielding effectiveness for electronics, and transparent WiFi/Bluetooth antennas for mobile devices like smartphones, tablets, laptops and all-in- one computers.

Aligned with SABIC’s focus to provide solutions that will solve industry challenges, SABIC engaged in a joint collaboration with Cima NanoTech in the latter half of 2013 to develop the promising new material, which will be available for customer trials later this year.

“Transparent conductive polycarbonate is a breakthrough material that customers in consumer electronics and other important industries have been seeking,” Matt Gray, Director of Marketing, Consumer Electronics for SABIC’s Innovative Plastics business, said. “Our work with Cima NanoTech is strategically aligned with our commitment to continuous innovation in areas of importance to our customers,” Gray noted.

The collaboration, leveraging both Cima NanoTech’s proprietary SANTE nanoparticle technology and SABIC’s LEXANTM film, a polycarbonate material, has resulted in the development of a new series of transparent conductive materials that are lightweight with excellent transparency, outstanding conductivity and high flexibility. Cima NanoTech worked with SABIC’s scientists to jointly develop materials that not only meet the requirements of existing industries, but also stretches the possibilities for exciting opportunities by breaking boundaries faced with current materials.

“We are very pleased to be working with SABIC to bring the key advantages of SANTE nanoparticle technology forward into a number of diverse consumer and industrial markets,” Jon Brodd, Chief Executive Officer, Cima NanoTech, stated. SANTE technology, a patented self-assembling nanoparticle technology platform, stands alone in providing high transparency with ultra-low electrical resistance, which is ten times better than the incumbent indium tin oxide (ITO). “In addition to its ability to meet optical grade specifications for display and touch applications, SANTE nanoparticle technology is also more cost effective as coating is performed via a wet coating, roll-to-roll process versus sheet-to-sheet,” Brodd said.

The conductive SANTE network is also mechanically robust, thus allowing it to withstand flexing, stretching, torsion and tension for flexible applications. The substrate can also be thermoformed into various curved and 3D form factors.

Cima NanoTech, a smart nanomaterials company specializing in high performance transparent conductive films, announced today the industry’s first ultra responsive, non-ITO film-based, 42-inch projected capacitive multi- touch module for large format touch applications. The module was built by Amdolla Group using Cima NanoTech’s highly conductive, silver nanoparticle-based, SANTE FS200 touch films. This product is targeted at applications including self-service kiosks, interactive tabletops, widescreen interactive digital signage, interactive flat panel displays, and other applications that require fast response, large size touch screens.

With a scan rate of 150hz for 10-point multi-touch, rivaling the response time of smartphones and tablets, this jointly developed product dramatically increases the speed of large format touch displays. Unlike optical and infrared touch solutions, this module does not have a raised bezel for a smooth cover glass. In addition, the random conductive mesh pattern formed by SANTE nanoparticle technology eliminates moiré, a challenge for traditional metal mesh technologies, thus enabling touch screens with better display quality.

“Our goal is to offer our customers a high performance, cost competitive and easy-to- implement solutions, and we’ve done it.” said Jon Brodd, CEO, Cima NanoTech. “Together with touch panel manufacturer, Amdolla, we are confident in creating a large format touch experience that is engaging and intuitive, and we expect to see this product on shelves by Q4 2014.”

SANTE FS200 touch films are manufactured via a wide width roll-to-roll wet coating process. The high-throughput, high-yield manufacturing makes SANTE nanoparticle technology a cost competitive solution for large format touch screens. Cima NanoTech also has the production capabilities to scale up to wider width touch films for screen sizes above 42”, further expanding the possibilities for innovative touch-enabled surfaces.

“The high response rate and excellent multi-point accuracy of the 42” touch module makes it a superior product in the industry, and we are very excited to be working with Cima NanoTech to commercialize this product,” commented Vance Zhang, General Manager, Amdolla Group. “We are also working to scale up to 55’’ screen sizes and larger.”

Cima NanoTech, a smart nanomaterials company specializing in high performance transparent conductors, showcased an ultra responsive, non-ITO film-based 42” large format touch screen at SID Display Week. Combining Cima NanoTech’s highly conductive SANTE FS200 touch films and specially engineered multi-chip touch controllers from Silicon integrated Systems Corp. (SiS), the 42” touch screen demo boasts an exceptional scan rate of 150hz for 10-point multi-touch, or a response time of 6.5 milliseconds, allowing end-users to enjoy the instantaneous touch response of smartphones and tablets on large and ultra large format touch displays.

The performance of today’s touch-enabled software is often constrained by the hardware technology accompanying it – and slow response time is one of the main issues. This compromise is even more evident in large format touch screens that are 30-inch and above – a high growth market for self-service retail kiosks, interactive flat panel displays, touch-enabled tabletops and many others. Engineered to possess high conductivity and mechanical flexibility, Cima NanoTech’s SANTE FS200 touch films allow touch panel manufacturers to keep pace with software developers, thus transforming the overall large format touch experience into one that is more enjoyable, interactive and engaging.

“We are excited to be working with SiS to develop best in class, ultra responsive, large format touch screens.” said Jon Brodd, CEO, Cima NanoTech. “We are confident that by leveraging the expertise of both companies, we can fully capitalize on the strong market potential of large format touch screens.”

By working directly with IC chip companies, Cima NanoTech is able to provide touch solutions that are easily integrated into their customer’s existing processes,

shortening the time-to-market of products. In addition, SANTE FS200 touch films are compatible with standard etching and lamination methods, enabling supply chain freedom for touch panel manufacturers.

“The superior multi-point accuracy, high response rate and high sensitivity of the 42” touch demo truly makes it a breakthrough product in the industry, and we look forward to see the innovative applications our customers will use this product for,” commented Eddie Chang, Vice President, Sales, SiS.

Specialty touch screen and display enhancement manufacturer, Touch International confirmed today the release of a new touch sensing technology that overcomes the limitations of current projected capacitive (p-cap) offerings. PCAP Plus technology features multi-touch with gestures and works with fingers, heavy gloves, or any other input device. Additionally, the sensor is designed with a unique construction that performs in compliance with military, aerospace, and medical EMI/RFI requirements.

“Our experience in the high reliability markets has shown a clear missing link between the features and limitations of resistive and projected capacitive touch technology,” says Michael Woolstrum, CEO. “With PCAP Plus, we’ve not only bridged the gap, but have also provided the added bonus of EMI/RFI performance. From the battlefield and the cockpit to the operating room, this changes everything.”

Touch International’s team of engineers at the Austin, Texas R&D center started with their latest projected capacitive sensor designs and ultra-thin controllers. Using an extensive library of proven components and advanced tuning of the controller, they developed a conductive upper displacement plate. The plate gives the sensor multi-input properties and EMI performance without compromising optical clarity or multi-touch abilities. The company also ensured the sensor can be built using the myriad of substrates and transparent conductors the market has to offer.

PCAP Plus is immune to on-screen contaminants, extreme temperatures, and works when submerged in water. While the company has developed traditional projected capacitive sensors with immunity to water mist, traditional projected capacitive remains unable to maintain full functionality with pooling water or completely submerged. Easy to use, PCAP Plus requires only light pressure to activate and is precise and highly responsive. PCAP Plus doesn’t require recalibration and is maintenance free.

One of the most common problems implementing projected capacitive technology is the electromagnetic interference or susceptibility. Independent lab tests on TI’s PCAP Plus show all sensors tested pass EMI/RFI compliance for MIL-STD-461F, DO-160E, and CISPR25. This enables military, aerospace, transportation, and medical designers or manufacturers to tackle EMI/RFI compliance and regulation issues easily at the component level.

“Since projected capacitive exploded on the market in 2007 with the iPhone, you haven’t really seen a ‘next big thing’ in touch,” says Shaun Detmer, Marketing Director. “The mission critical markets have been, in many applications, stuck with outdated resistive technology. Those days are over.”

All PCAP Plus touch sensors work with Windows 7/8 as well as other operating systems, but must be customized for customer specific enclosures and displays. Sensors are available with I2C or plug-n-play USB connectivity. Current designs can be scaled up to 12 inches and will be available up to 24 inches in Q2 2014. Demo kits are available built to order and can feature add-ons such as sunlight readable displays and optical bonding.

Cypress Semiconductor Corp. today announced the US Patent Office has issued Cypress its one hundredth patent related to its TrueTouch capacitive touchscreen controllers. The patent, numbered 8,610,443, relates to attenuator circuits that contribute to the TrueTouch Gen5 family’s unmatched immunity to electrical noise from chargers and displays, which can render touchscreens for smartphones, superphones, tablets, e-readers and other portable devices unusable. Cypress is continuing to expand its intellectual property (IP) portfolio at the industry’s highest rate with more than 200 patents pending, protecting the competitive advantage of its TrueTouch offerings and their differentiating features.

In addition to patents related to noise immunity, Cypress’s patented DualSense technology allows TrueTouch solutions to execute both self-capacitance and mutual-capacitance measurements in the same device. This enables the Gen5 family to offer the industry’s best waterproofing for seamless performance in real-world conditions, including the presence of rain, condensation or sweat. Cypress also holds patents related to panel construction, mutual capacitance sensing, scanning methods, setting baselines, and tracking and identification of fingers, styluses and other objects.

Cypress is demonstrating its TrueTouch portfolio in customer meetings at the Consumer Electronics Show in Las Vegas, Nevada from January 7-10, 2014.

“Earning our one hundredth capacitive touch related patent demonstrates both the strength of our touchscreen IP portfolio and the true technological innovation behind the unique features and leading performance of our TrueTouch solutions,” said John Carey, Senior Director of TrueTouch Marketing at Cypress. “With more than 200 more patents currently pending, Cypress is committed to continuing development of differentiating features that enable our customers to create the market’s next-generation products.”

The TrueTouch Gen5 family’s ChargerArmor feature delivers unprecedented 40 volt peak-to-peak (Vpp) charger noise immunity measured from 1 to 500 kHz with an ultra-thin 0.5-mm cover lens and a finger-size up to 22 mm—the most stringent specifications used to measure any touchscreen controller. No competing controllers deliver noise immunity over 10 Vpp under these conditions. And with a more common finger size of 9 mm, Gen5 controllers deliver 60 Vpp. Another patented element of TrueTouch’s noise resistance is its unique ability to deliver on-chip 10V Tx and Tx-Boost, a multi-phase Tx solution to increase signal strength as needed, providing an unmatched signal-to-noise ratio.

Gen5 controllers drive the touchscreen at 10V and at high frequency with narrow-band, single-pass scanning and advanced hardware DSP filtering. By combining this powerful architecture with an industry leading 32-bit ARM Cortex M-Core processor that is known for high-efficiency MIPS/mW, the family boasts 120-Hz refresh rates, and averages low power consumption of 12 mW in active mode and 15 uW in deep-sleep mode. The family’s unmatched noise immunity enables designers of next-generation handsets to implement ultra-thin, display-integrated stackups, including In-Cell, On-Cell, and direct lamination onto a noisy display. The result will be thinner, sleeker end-products with a flawless user experience.

After a decline in the second quarter of 2013 and a tepid expansion in the third, demand for touch-screen panels used in notebook PCs is set to rebound to double-digit growth during the last three months of the year.

Shipments of touch panels for notebooks will amount to 4.9 million sheets in the fourth quarter, up 10 percent from 4.4 million in the third quarter, according to data from the “Touch Panel Shipments Database – Notebook” report from IHS Inc. This follows a marginal 2 percent increase in the third quarter and a 5 percent drop in the second, as presented in the attached figure.

Screen Shot 2013-12-12 at 4.21.34 PM

“While the overall notebook PC market remains sluggish, sales of touch panels for notebook PCs are showing some signs of life in the fourth quarter,” said Stone Wu, principal analyst for display components and materials at IHS. “The resumption of double-digit growth is being driven by the full-scale launch of 10.1-inch touch-screen panels that appeal to consumers, along with the introduction of a new microprocessor solution and the arrival of exciting new form factors.”

Related: PC outlook lowered again

A touch-and-go market

Despite the growth in the second half of the year, demand for laptops with touch panels is falling short of expectations in 2013. Overall shipments of notebooks have been weak this year because of the continuing inroads of media tablets into consumer demand. This has slowed growth even in the hot touch-screen notebook segment.

Related: Tablet display market more than doubles in Q1

However, even with the disappointing growth, shipments of notebook touchscreen panels will rise to 18.2 million sheets in 2013, up nearly 500 percent from 3.2 million in 2012. This makes touch-screen notebooks the fastest-growing segment of the PC market today.

Wintel to the rescue

The notebook touch-screen panel market in the second half has been boosted by the launch of products based on the new low-power Atom Bay Trail central processing unit (CPU) chip from Intel Corp.

The market also is getting a lift from the release of two-in-one convertible form-factor notebooks that have detachable displays.

Shipments of notebook touch-screen panels that are smaller than 10.1 inches are expected to flourish in the near term thanks to heavy subsidies to be provided by Intel and Microsoft for laptops with touch-screen panels and utilizing the Atom chip or the Windows 8.1 operating system.

Third-quarter woes

Even with the rise in shipments in the third quarter, the notebook touch-screen panel market dwindled in terms of shipment area and revenue compared to the second quarter.

The average shipments area per unit in the third quarter was 0.065 square meters (sqm), or 4.1 percent smaller than the 0.068 sqm of the second quarter.

Market revenue for notebook touch-screen panels came to $190.2 million, down 12.8 percent from the second quarter. Pricing was impacted by an oversupply of panels, particularly in the large-sized laptop market.

In terms of form factors for notebooks with touch-screen panels, the most prominent change in the third quarter was the decrease in clamshell types, with their share of market shipments falling to 63.4 percent, down from 75.2 percent in the second quarter. Meanwhile, the detachable segment rose to 16.9 percent, up from 11.5 percent. Tablet form-factor types rose to 12.7 percent, up from 5.5 percent.

Much of the growth in the detachable and tablet form factors is attributed to the heavy subsidies originating from Intel and Microsoft.

How bad were conditions in the notebook PC market during the second quarter?

So bad that that even the red-hot segment of display panels for touch-screen mobile PCs suffered a sequential decline during the period, according to a new report entitled “Touch Panel Shipment Database – Notebook PC – Q3 2013,” published by IHS.

Shipments of touch-screen panels for notebook PC amounted to 4.4 million units in the second quarter of 2013, down 4.9 percent from 4.6 million in the previous quarter, as presented in the attached figure. Up until the second quarter, shipments of these panels had been skyrocketing, rising by 52 percent in the first quarter, by nearly 3,000 percent in the fourth quarter of 2012 and by 222 percent in the third quarter of 2012.

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Despite the sequential decline, the nascent market for notebook touch screens still is expanding explosively on a year-over-over basis, with shipments surging to 8.9 million units in the first half of 2013, up from a mere 53,000 in the first half of 2012.

“The touch-screen notebook market stalled in the second quarter, reflecting generally terrible conditions in the mobile PC segment,” said Duke Yi, senior manager for display components and materials research at IHS. “Shipment growth also was impacted as PC makers prepared new models for introduction in the second half of 2013. The good news for the market is that sequential growth is forecast to recover in the second half, traditionally the peak season for PC product sales, following launches of new product lineups.”

Second-quarter blues

Worldwide shipments of all types of mobile PCs—including both conventional and touch-screen models—shrank a steep 5.1 percent during the April to June period compared to the first three months of the year. This represented the first time the notebook PC market experienced a sequential decline since the second quarter of 2002, during the dot-com bust. The mobile PC industry this time faced tough competition from media tablets, depressing sales.

Area reprieve

While unit shipments declined in the second quarter, the market for notebook PC touch screens actually expanded based on another growth metric: panel area. Mobile PC touch-screen-panel shipments measured in terms of square inches rose by 3.4 percent in the second quarter compared to the first. This indicates that display sizes for touch-screen notebooks are expanding.

Notebook touch panels sized 11.6 inches or smaller accounted for 36.8 percent of total shipments in the second quarter, down from 52.7 percent during the previous quarter. Meanwhile, combined shipments of 13.3- , 14- , and 15.6-inch laptop touch panels, which have emerged as the mainstream sizes, jumped to 57.1 percent of the total market, up from 40.1 percent in the first quarter.

Price plunge

Although touch-panel shipments by area increased quarter-on-quarter, prices of touch panels fell significantly amid intensifying competition. The average selling price of laptop touch panels dropped more than 10 percent, despite growing demand for larger touch-screen panels.

Meanwhile, the utilization of low-end technologies has been on the rise. For example, the use of sodalime for the cover glass of a notebook touch panel has increased, replacing aluminosilicate, which made up 35.7 percent of the cover-glass market in the second quarter, down from 65.7 percent in the previous quarter.

The growing adoption of low-end technologies in the notebook PC sector indicates ongoing efforts in the market to cut touch-panel costs while expanding touch-screen notebook PC displays to be as large as those used in conventional notebook PCs.

Happy as a clamshell

Traditional clamshell PCs in the second quarter accounted for 75 percent of total touch-screen notebooks, up from 58 percent during the same period in 2012. Meanwhile, the market share for high-end detachable-type touch-screen notebook PC fell to 11.5 percent, down from 23.7 percent. Development costs for clamshell notebooks are lower than those of other form factors, prompting greater participation from PC makers.

Amid increasing competition, display supplier TPK Holding Co. from Taiwan lost share during the second quarter in the notebook PC touch-screen panel market. The company’s share of market dropped to less than 50 percent. Meanwhile, AU Optronics Corp., also from Taiwan, and China’s Shenzhen O-Film Tech Co. posted rapid growth during the same period. Notebook PC makers on the whole have been diversifying touch screen panel suppliers to reduce the prices of the panels.

The market for controller integrated circuits (ICs) used for the laptop touch screen panels was also hit by fierce competition. California-based Atmel Corp., which previously led the market, lost ground to Taiwan’s ELAN Microelectronics Corp. in the second quarter. Two other entities expanded their market share—Synaptics Inc., also of California; and eGalax-eMPIA Technology Inc., another Taiwanese maker.

IHS timely published a quarterly “Touch Panel Shipment Database – Notebook PC” report to help them understanding the notebook-use projected capacitive touch panel industry quickly and accurately. The report provides quarterly shipments of touch-screen notebooks by unit/area/value; by inch; by brand; by form factor; by touch panel layer; by touch panel module and controller IC maker; and by cover window materials and bonding type, as well as top five models in terms of shipments.

The report should offer insight into the related market and industry to notebook set makers that are interested in notebook-use projected capacitive touch panels and companies related to touch panel modules, parts and raw materials.

Electronic devices with touchscreens are ubiquitous, and one key piece of technology makes them possible: transparent conductors. However, the cost and the physical limitations of the material these conductors are usually made of are hampering progress toward flexible touchscreen devices.

Fortunately, a research collaboration between the University of Pennsylvania and Duke University has shown a new a way to design transparent conductors using metal nanowires that could enable less expensive — and flexible — touchscreens.

The research was conducted by graduate student Rose Mutiso, undergraduate Michelle Sherrott and professor Karen Winey, all of the Department of Materials Science and Engineering in Penn’s School of Engineering and Applied Science. They collaborated with graduate student Aaron Rathmell, and professor Benjamin Wiley of Duke’s Department of Chemistry.

Their study was published in the journal ACS Nano.

The current industry-standard material for making transparent conductors is indium tin oxide, or ITO, which is deposited as two thin layers on either side of a separator film. Contact, in the form of a fingertip or a stylus, changes the electrical resistance between the two ITO layers enough so that the device can register where the user is touching. While this material performs well, its drawbacks have led industrial and academic researchers to look for alternatives.

“There are two problems with ITO; indium is relatively rare, so its cost and availability are erratic, and, more importantly for flexible devices, it’s brittle,” Winey said. “We’d like to make touchscreens that use a network of thin, flexible nanowires, but predicting and optimizing the properties of these nanoscale networks has been a challenge.”

Metal nanowires are increasingly inexpensive to make and deposit; they are suspended in a liquid and can easily be painted or sprayed onto a flexible or rigid substrate, rather than grown in vacuum as is the case for ITO. The challenge stems from the fact that this process forms a random network, rather than a uniform layer like ITO.

A uniform sheet’s overall quality in this context depends on only two parameters, both of which can be reliably derived from the bulk material’s properties: its transparency, which should be high, and its overall electrical resistance, which should be low. To determine the electrical properties for a network of nanowires, however, one needs to know the nanowires’ length and diameter, the area they cover and a property known as contact resistance, which is the amount of resistance that results from electrons traveling from one wire to another. The details of how these four independent parameters impact the electrical and optical properties of nanowire networks have been unclear.

“What this means is that people will synthesize nanowires, deposit them in a network, measure the network’s overall electrical resistance and optical properties and then claim victory when they get a good one,“ Winey said. “The problem is that they don’t know why the good ones are good, and, worse, they don’t necessarily know why the bad ones are bad.”

For example, low overall resistance could be the result of a particular synthesis method that produced a few unexpectedly long nanowires, or a processing method that reduced the contact resistance between nanowires. Without a way of isolating these factors, researchers can’t determine which combination of parameters will be most successful.

Winey’s group has previously worked on simulating nanowire networks in three-dimensional nanocomposites, particularly the number of nanowires it takes to ensure there is a connected path from one end of the system to the other. Duke’s Wiley took note of this work and contacted Winey, asking her if she would be interested in developing two-dimensional simulations that could be applied to data from silver nanowire networks his group had fabricated.

With Wiley’s group able to provide the nanowire length, diameter and area fraction of their networks, Winey’s team was able to use the simulation to work backward from the network’s overall electrical resistance to uncover the elusive contact resistance. Alternative methods for finding the contact resistance are laborious and incompatible with typical network processing methods.

“Once we have reliable and relevant contact resistances, we can start asking how we can improve the overall sheet resistance by changing the other variables,” Mutiso said. “In playing with this simulation, we can see how much better our networks get when we increase the length of the nanowires, for example.”

The Penn team’s simulation provides further evidence for each variable’s role in the overall network’s performance, helping the researchers home in on the right balance of traits for specific applications. Increasing the coverage area of nanowires, for example, always decreases the overall electrical resistance, but it also decreases optical transparency; as more and more nanowires are piled on the networks appear gray, rather than transparent.

“For specific applications and different types of nanowires, the optimal area fraction is going to be different,” Winey said. “This simulation shows us how many nanowires we need to apply to reach the Goldilocks zone where you get the best mix of transparency and resistance.”

Future collaborations between Winey’s team at Penn and the Wiley group at Duke will use this simulation to test the effect of different processing techniques on nanowires, pinpointing the effect various post-deposition processing methods has on contact resistance and ultimately on overall sheet resistance.

“We can now make rational comparisons between different wires, as well as different processing methods for different wires, to find the lowest contact resistance independent of nanowire length, diameter and area fraction,” Winey said. “Now that we know where all the levers are, we can start adjusting them one at a time.”

In the next generation of modeling studies, the Penn team will consider several additional parameters that factor into the performance of nanowire networks for transparent conductors, including nanowire orientation, to mimic nanowire networks produced by various continuous deposition methods, as well as the degree to which individual nanowires vary in length or diameter.

The research was supported by the National Science Foundation and Penn’s Materials Science Research and Engineering Center.

Michelle Sherrott is now a doctoral student in materials science at the California Institute of Technology.