Tag Archives: letter-leds-top

New approach for “nanohoops” could energize future devices

October 14, 2015

When University of Oregon associate professor Ramesh Jasti began making tiny organic circular structures using carbon atoms, the idea was to improve carbon nanotubes being developed for use in electronics or optical devices. He quickly realized, however, that his technique might also roll solo.

In a new paper, Jasti and five University of Oregon colleagues show that his nanohoops — known chemically as cycloparaphenylenes — can be made using a variety of atoms, not just those from carbon. They envision these circular structures, which efficiently absorb and distribute energy, finding a place in solar cells, organic light-emitting diodes, or as new sensors or probes for medicine.

Though barely one-nanometer, nanohoops offer a new class of structures for use in energy or light devices. (Courtesy of Ramesh Jasti)

The research, led by Jasti’s doctoral student Evan R. Darzi, was described in a paper placed online ahead of print in ACS Central Science, a journal of the American Chemical Society. The paper is a proof-of-principle for the process, which will have to wait for additional research to be completed before the full impact of these new nanohoops can be realized, Jasti said.

These barely one-nanometer nanohoops offer a new class of structures — sized between those made with long-chained polymers and small, low-weight molecules — for use in energy or light devices, said Jasti, who was the first scientist to synthesize these types of molecules in 2008 as a postdoctoral fellow at the Molecular Foundry at the Lawrence Berkeley National Laboratory.

“These structures add to the toolbox and provide a new way to make organic electronic materials,” Jasti said. “Cyclic compounds can behave like they are hundreds of units long, like polymers, but be only six to eight units around. We show that by adding non-carbon atoms, we are able to move the optical and electronic properties around.”

Nanohoops help solve challenges related to materials with controllable band gaps — the energies that lie between valance and conduction bands and is vital for designing organic semiconductors. Currently long materials such as those based on polymers work best.

“If you can control the band gap, then you can control the color of light that is emitted, for example,” Jasti said. “In an electronic device, you also need to match the energy levels to the electrodes. In photovoltaics, the sunlight you want to capture has to match that gap to increase efficiency and enhance the ability to line up various components in optimal ways. These things all rely on the energy levels of the molecules. We found that the smaller we make nanohoops, the smaller the gap.”

To prove their approach could work, Darzi synthesized a variety of nanohoops using both carbon and nitrogen atoms to explore their behavior. “What we show is that the charged nitrogen makes a nanohoop an acceptor of electrons, and the other part becomes a donator of electrons,” Jasti said.

“The addition of other elements like nitrogen gives us another way to manipulate the energy levels, in addition to the nanohoop size. We’ve now shown that the nanohoop properties can be easily manipulated and, therefore, these molecules represent a new class of organic semiconductors — similar to conductive polymers that won the Nobel Prize in 2000,” he said. “With nanohoops, you can bind other things in the middle of the hoop, essentially doping them to change properties or perhaps sense an analyte that allows on-off switching.”

His early work making nanohoop compounds was carbon-based, with the idea of making them different diameters and then combining them, but his group kept seeing unique and unexpected electronic and optical properties.

Jasti, winner of a National Science Foundation Career Award in 2013, brought his research from Boston University to the UO’s Department of Chemistry and Biochemistry in 2014. He said the solar cell research being done by his colleagues in the Materials Science Institute, of which he is a member, was an important factor in his decision to move to the UO.

“We haven’t gotten very far into the application of this,” he said. “We’re looking at that now. What we were able to see is that we can easily manipulate the energy levels of the structure, and now we know how to exchange any atom at any position along the loop. That is the key discovery, and it could be useful for all kinds of semiconductor applications.”

Co-authors with Darzi and Jasti were: former BU doctoral student Elizabeth S. Hirst, who now is a postdoctoral fellow at the U.S. Army Natick Soldier Research, Development and Engineering Center; UO doctoral student Christopher D. Weber; Lev N. Zakharov, director of X-ray crystallography in the UO’s Advanced Materials Characterization in Oregon center; and Mark C. Lonergan, a professor in the Department of Chemistry and Biochemistry.

The NSF (grant CHE-1255219), Department of Energy (DE-SC0012363), Sloan Foundation and Camille and Henry Dreyfus Foundation supported the research.

New findings move flexible lighting technology toward commercial feasibility

September 4, 2015

Imagine illuminating your home or business with flat, inexpensive panels that are environmentally friendly, easy on your eyes, and energy-efficient because they create minimal heat.

Now imagine how those panels could be used if they were as flexible as paper or cloth; the technology could be bent into shapes, fit the interior or exterior curves of vehicles, even be incorporated into clothing.

In “Flexible organic light-emitting diodes (OLEDs) for solid-state lighting” a team of researchers at Pohang (Republic of Korea) University of Science and Technology reports on advances in three key areas — flexible electrodes, flexible encapsulation methods, and flexible substrates — that make commercial use of such technology more feasible and closer to implementation. The article appears in the current issue of the Journal of Photonics for Energy, published by SPIE, the international society for optics and photonics.

Figure 9 from a new article in the Journal of Photonics for Energy is a schematic illustration of OLED structures with encapsulation: (a) conventional glass lid and (b) thin-film encapsulation. Credit: Min-Ho Park et al., Pohang University

OLEDs show promise as a future light source because of their thinness, light weight, energy efficiency, and use of environmentally benign materials. Companies such as Philips and LG Chemical have begun producing flat OLED panels that produce non-glare, UV-free light but very little heat, with no need for lamp shades or diffusers.

“The future trend in OLEDs is to make them on plastic substrates for flexibility, durability, and light weight. In this work, the authors review the technical challenges and solutions in this important subject,” said Franky So, Walter and Ida Freeman Distinguished Professor in Materials Science and Engineering at North Carolina State University, and an associate editor of the journal.

Min-Ho Park and other researchers at Pohang tested a variety of transparent electrodes as flexible alternatives to currently available devices based on indium tin oxide (ITO), which is brittle and increasingly expensive, and identified next steps toward making flexible solid-state lighting commercially feasible:

development of a flexible electrode that has high electrical conductivity, high bending stability, few defects, smooth surface texture, and high work function
reduction in the water-vapor transmission rate of materials used, to counter the vulnerability of OLEDs to moisture.

OLEDs produce light by sending electricity through one or more thin layers of an organic semiconductor, which may be composed of any of a variety of materials and as small a as a molecule. The semiconductor is sandwiched between a positively charged electrode and a negatively charged one. These layers are deposited on a supporting surface called a substrate, and protected from exposure to the air by a thin layer of encapsulants (traditionally glass).

The Pohang team demonstrated good electrical, optical, and mechanical performance with flexible electrodes fabricated using graphene, conducting polymers, silver nanowires (AgNWs), and dielectric-metal-dielectric (DMD) multilayer structures.

However, various obstacles still remain with these devices’ durability, conductivity, surface roughness, and fabrication cost. Current flexible substrates and encapsulation methods are being explored, with the goal of reducing cost and processing time, and increasing durability.

Global semiconductor sales down slightly in July

September 4, 2015

The Semiconductor Industry Association (SIA) today announced worldwide sales of semiconductors were $27.9 billion for the month of July 2015, a decrease of 0.9 percent from July 2014 when sales were $28.1 billion. Global sales from July 2015 were 0.4 percent lower than the June 2015 total of $28.0 billion. Regionally, sales in the Americas were roughly flat in July compared to last year, while sales in China increased by nearly 6 percent. All monthly sales numbers are compiled by the World Semiconductor Trade Statistics (WSTS) organization and represent a three-month moving average.

“Global semiconductor sales have slowed somewhat this summer in part due to softening demand, normal market cyclicality, and currency devaluation in some regional markets,” said John Neuffer, president and CEO, Semiconductor Industry Association. “Despite these headwinds, year-to-date global sales through July are higher than at the same time last year, which was a record year for semiconductor revenues.”

Regionally, year-to-year sales increased in China (5.6 percent), Asia Pacific/All Other (1.0 percent), and the Americas (0.8 percent), but decreased in Europe (-12.5 percent) and Japan (-13.3 percent), in part due to currency devaluation. On a month-to-month basis, sales increased in Japan (2.7 percent), China (0.6 percent), and Europe (0.4 percent), but fell slightly in the Americas (-0.3 percent) and Asia Pacific/All Other (-2.5 percent).

“One key facilitator of continued strength in the U.S. semiconductor industry is research, the lifeblood of innovation,” Neuffer said. “SIA and Semiconductor Research Corporation this week released a report highlighting the urgent need for research investments to advance the burgeoning Internet of Things and develop other cutting-edge, semiconductor-driven innovations. Implementing the recommendations in the report will help the United States harness new technologies and remain the world’s top innovator.”

July 2015
Billions
Month-to-Month Sales
Market	Last Month	Current Month	% Change
Americas	5.53	5.52	-0.3%
Europe	2.83	2.84	0.4%
Japan	2.57	2.64	2.7%
China	8.13	8.18	0.6%
Asia Pacific/All Other	8.94	8.71	-2.5%
Total	27.99	27.88	-0.4%

Year-to-Year Sales
Market	Last Year	Current Month	% Change
Americas	5.47	5.52	0.8%
Europe	3.24	2.84	-12.5%
Japan	3.04	2.64	-13.3%
China	7.75	8.18	5.6%
Asia Pacific/All Other	8.63	8.71	1.0%
Total	28.13	27.88	-0.9%

Three-Month-Moving Average Sales
Market	Feb/Mar/Apr	May/Jun/Jul	% Change
Americas	5.61	5.52	-1.7%
Europe	2.89	2.84	-1.8%
Japan	2.54	2.64	3.8%
China	7.77	8.18	5.2%
Asia Pacific/All Other	8.74	8.71	-0.3%
Total	27.56	27.88	1.2%

“Quantum dot” technology may help light the future

August 19, 2015

Advances at Oregon State University in manufacturing technology for “quantum dots” may soon lead to a new generation of LED lighting that produces a more user-friendly white light, while using less toxic materials and low-cost manufacturing processes that take advantage of simple microwave heating.

The cost, environmental, and performance improvements could finally produce solid state lighting systems that consumers really like and help the nation cut its lighting bill almost in half, researchers say, compared to the cost of incandescent and fluorescent lighting.

The same technology may also be widely incorporated into improved lighting displays, computer screens, smart phones, televisions and other systems.

A key to the advances, which have been published in the Journal of Nanoparticle Research, is use of both a “continuous flow” chemical reactor, and microwave heating technology that’s conceptually similar to the ovens that are part of almost every modern kitchen.

The continuous flow system is fast, cheap, energy efficient and will cut manufacturing costs. And the microwave heating technology will address a problem that so far has held back wider use of these systems, which is precise control of heat needed during the process. The microwave approach will translate into development of nanoparticles that are exactly the right size, shape and composition.

“There are a variety of products and technologies that quantum dots can be applied to, but for mass consumer use, possibly the most important is improved LED lighting,” said Greg Herman, an associate professor and chemical engineer in the OSU College of Engineering.

“We may finally be able to produce low cost, energy efficient LED lighting with the soft quality of white light that people really want,” Herman said. “At the same time, this technology will use nontoxic materials and dramatically reduce the waste of the materials that are used, which translates to lower cost and environmental protection.”

Some of the best existing LED lighting now being produced at industrial levels, Herman said, uses cadmium, which is highly toxic. The system currently being tested and developed at OSU is based on copper indium diselenide, a much more benign material with high energy conversion efficiency.

Quantum dots are nanoparticles that can be used to emit light, and by precisely controlling the size of the particle, the color of the light can be controlled. They’ve been used for some time but can be expensive and lack optimal color control. The manufacturing techniques being developed at OSU, which should be able to scale up to large volumes for low-cost commercial applications, will provide new ways to offer the precision needed for better color control.

By comparison, some past systems to create these nanoparticles for uses in optics, electronics or even biomedicine have been slow, expensive, sometimes toxic and often wasteful.

Oher applications of these systems are also possible. Cell phones and portable electronic devices might use less power and last much longer on a charge. “Taggants,” or compounds with specific infrared or visible light emissions, could be used for precise and instant identification, including control of counterfeit bills or products.

OSU is already working with the private sector to help develop some uses of this technology, and more may evolve. The research has been supported by Oregon BEST and the National Science Foundation Center for Sustainable Materials Chemistry.

Imec pushes the boundaries of GaN technology

August 12, 2015

Nano-electronics research center imec announced today that it is extending its Gallium Nitride-on-Silicon (GaN-on-Si) R&D program, and is now offering joint research on GaN-on-Si 200mm epitaxy and enhancement mode device technology. The extended R&D initiative includes exploration of novel substrates to improve the quality of the epitaxial layers, new isolation modules to increase the level of integration, and the development of advanced vertical devices. Imec welcomes new partners interested in next generation GaN technologies and companies looking for low-volume manufacturing of GaN-on-Si devices to enable the next generation of more efficient and compact power converters.

GaN technology offers faster switching power devices with higher breakdown voltage and lower on-resistance than silicon, making it an outstanding material for advanced power electronic components. Imec’s R&D program on GaN-on-Si was launched to develop a GaN-on-Si process and bring GaN technology towards industrialization. Building on imec’s excellent track record in GaN epi-layer growth, new device concepts and CMOS device integration, imec has now developed a complete 200mm CMOS-compatible GaN process line. Imec’s GaN-on-Si technology is reaching maturity, and companies can gain access to the platform by joining imec’s GaN-on-Si industrial affiliation program (IIAP). The process line is also open to fabless companies interested in low-volume production of GaN-on-Si devices tailored to their specific needs, through dedicated development projects.

Imec’s portfolio includes three types of buffers optimized for breakdown voltage and low traps-related phenomena (i.e. current dispersion): a step graded AlGaN buffer, a super lattice buffer, and a buffer with low-temperature AlN interlayers. Imec explored side-by-side enhancement mode power devices of the MISHEMT and p-GaN HEMT type, as well as a gate-edge terminated Schottky power diode featuring low reverse leakage and low turn-on voltage.

The latest generation of imec enhancement mode power devices shows a threshold voltage beyond +2V, an on-resistance below 10 ohm mm and output current beyond 450 mA/mm. These devices represents the state of the art of enhancement mode power devices.

In this next phase of the GaN program, imec is focusing on further improving the performance and reliability of its current power devices, while in parallel pushing the boundaries of the technology through innovation in substrate technology, higher levels of integration and exploration of novel device architectures.

“Since the program’s launch in July 2009, we have benefited from strong industry engagement, including participation from IDMs, epi-vendors and equipment and material suppliers. This underscores the industrial relevance of our offering,” stated Rudi Cartuyvels, executive vice president of smart systems at imec. “Interested companies are invited to become a partner and actively participate in our program. Imec’s open innovation model allows companies to have early access to next-generation devices and power electronics processes, equipment and technologies and speed up innovation at shared cost.”

New research may enhance display & LED lighting technology

August 10, 2015

Recently, quantum dots (QDs)–nano-sized semiconductor particles that produce bright, sharp, color light–have moved from the research lab into commercial products like high-end TVs, e-readers, laptops, and even some LED lighting. However, QDs are expensive to make so there’s a push to improve their performance and efficiency, while lowering their fabrication costs.

Researchers from the University of Illinois at Urbana-Champaign have produced some promising results toward that goal, developing a new method to extract more efficient and polarized light from quantum dots (QDs) over a large-scale area. Their method, which combines QD and photonic crystal technology, could lead to brighter and more efficient mobile phone, tablet, and computer displays, as well as enhanced LED lighting.

To demonstrate their new technology, researchers fabricated a novel 1mm device (aka Robot Man) made of yellow photonic-crystal-enhanced QDs. Every region of the device has thousands of quantum dots, each measuring about six nanometers. Credit: Gloria See, University of Illinois at Urbana-Champaign

With funding from the Dow Chemical Company, the research team, led by Electrical & Computer Engineering (ECE) Professor Brian Cunningham, Chemistry Professor Ralph Nuzzo, and Mechanical Science & Engineering Professor Andrew Alleyne, embedded QDs in novel polymer materials that retain strong quantum efficiency. They then used electrohydrodynamic jet (e-jet) printing technology to precisely print the QD-embedded polymers onto photonic crystal structures. This precision eliminates wasted QDs, which are expensive to make.

These photonic crystals limit the direction that the QD-generated light is emitted, meaning they produce polarized light, which is more intense than normal QD light output.

According to Gloria See, an ECE graduate student and lead author of the research reported this week in Applied Physics Letters, their replica molded photonic crystals could someday lead to brighter, less expensive, and more efficient displays. “Since screens consume large amounts of energy in devices like laptops, phones, and tablets, our approach could have a huge impact on energy consumption and battery life,” she noted.

“If you start with polarized light, then you double your optical efficiency,” See explained. “If you put the photonic-crystal-enhanced quantum dot into a device like a phone or computer, then the battery will last much longer because the display would only draw half as much power as conventional displays.”

To demonstrate the technology, See fabricated a novel 1mm device (aka Robot Man) made of yellow photonic-crystal-enhanced QDs. The device is made of thousands of quantum dots, each measuring about six nanometers.

“We made a tiny device, but the process can easily be scaled up to large flexible plastic sheets,” See said. “We make one expensive ‘master’ molding template that must be designed very precisely, but we can use the template to produce thousands of replicas very quickly and cheaply.”

Apple is using 20% of worldwide sapphire capacity â and that may be just the beginning

July 31, 2015

Sapphire is the key material for LED manufacturing. But in 2015, 20 percent of sapphire will be used in Apple’s iPhone, for the camera lens, fingerprint readers and heart rate monitors covers, and the Apple watch’s window. The new Yole Développement (Yole) report on Sapphire Applications & Market 2015: from LED to Consumer Electronic provides a complete update of all sapphire uses, from LED substrates to consumer applications.

Today, the sapphire industry looks very different, depending on your perspective. The market for sapphire wafers for LED manufacturing is depressed. Wafer prices often fall below manufacturing cost. There is excess capacity that will be able to supply the needs of the industry through to at least the end of the decade. Consequently, companies are shutting down one after the other.

By contrast, the use of sapphire is booming for non-LED applications, driven by Apple’s choice of this material to protect various sensors, and this may be just the beginning. The company decided not to use sapphire for the iPhone 6 family’s display covers, a decision that led to the bankruptcy of GTAT. But now there are signs in the industry that the mobile phone maker is again looking at sapphire as the solution for display covers. Multiple companies are apparently attempting to position themselves in the potential future supply chain. The moves include Lens Technology investing US$532 million investment in a new Chinese sapphire facility, a US$98 million injection in GTAT, the plans of Biel’s joint venture with Roshow for a huge expansion in Inner Mongolia, and several other initiatives.

Click to view full size.

There were many reasons for Apple’s 2014 decision not to use sapphire in display covers, but they can be summarized as “too fast, too much, too soon.” The project was ambitious in its timeframe and targeted outputs, but many of the necessary processes and technologies in crystal growth and finishing were still at an early stage of development. Yet the venture still set the stage for the future. The partners have developed unrivalled expertise in working with sapphire in a high-volume, cost-controlled environment. A lot was also learned in manufacturing of the complex 3D-shaped Apple Watch cover. But the question remains: why use sapphire?

At more than five times the cost of glass, benefits in term of breakages are still far from obvious and its high reflectivity washes out displays. Sapphire won’t sell for a premium and increase Apple’s market share just on glamour and cachet. If the company eventually adopts sapphire, it means that it would have either demonstrated that it can improve breakage resistance compared to glass and/or developed entirely new functionalities enabled by some unique properties of sapphire.

To exist and thrive, the display cover market needs Apple to take the lead and to succeed. Otherwise, only Huawei seems in a position to propel this market, but not at the same level. And alternative technologies are emerging. Various phone manufacturers recently adopted alumina-coated glass display covers to provide superior scratch resistance. Sapphire Applications & Market 2015: from LED to Consumer Electronic report from Yole presents and analyzes the recent trends in this market, including cost structures, investments and alternative technologies.

In 2015, LEDs still consume 76 percent of the sapphire supply, but oversupply is affecting revenue and profitability. Capacity has increased non-stop since 2009, despite prices being at or below cost for most suppliers since late 2011. The market is oversupplied two or threefold, depending on product category. But the situation is complex. Tier one vendors often operate at high utilization rates and keep increasing capacity. Tier two companies operate at low utilization rates or not at all.

Companies such as BIEMT or Sumitomo Metal Mining recently disappeared or exited the business. The big winners in 2014 were Monocrystal, Aurora, Namiki, Rigidtech and Crystalwise, which all managed to increase volumes and revenue. Global revenue from sapphire cores, bricks and wafers reached US$1.1 billion. Adding finished components produced by Biel, Lens Technology, Crystal Optech and others, revenue reached US$1.8 billion, including the notable performance of Saifei, which supplied the Kyocera Brigadier’s sapphire display cover.

Under strong price pressure, the sapphire industry successfully reduced its costs – but prices are falling even faster. An 18 percent average selling price decrease in 2015 wiped out potential gains from a 16 percent volume increase in LED wafer shipments. “We expect prices to keep decreasing, resulting in an LED wafer market remaining essentially flat in revenue despite a 5.2 percent CAGR growth in volume expected through to 2020,” said Eric Virey, Senior, Technology & Market Analyst at Yole. Optical wafers may also struggle if Yole’s scenario of Apple phasing out its current sapphire fingerprint reader technology for an “In Display” fingerprint sensor materializes in 2018.

Tsunami of M&A deals underway in the semiconductor industry in 2015

July 29, 2015

IC Insights’ new 185-page Mid-Year Update to The McClean Report, which will be released later this week, examines the recent surge of M&A activity, including China’s aggressive new programs aimed at bolstering its presence in the semiconductor industry.

It would be hard to characterize the huge wave of semiconductor mergers and acquisitions occurring in 2015 as anything but M&A mania, or even madness. In just the first six months of 2015 alone, announced semiconductor acquisition agreements had a combined total value of $72.6 billion (Figure 1), which is nearly six times the annual average for M&A deals struck during the five previous years (2010-2014).

Figure 1

Three enormous acquisition agreements in 1H15 have already catapulted 2015 into the M&A record books. First, NXP announced an agreement in March to buy Freescale for $11.8 billion in cash and stock. In late May, Avago announced a deal to acquire Broadcom for about $37 billion in cash and stock, and then four days later (on June 1), Intel reported it had struck an agreement to buy Altera for $16.7 billion in cash. Avago’s astonishing deal to buy Broadcom is by far the largest acquisition agreement ever reached in the IC industry.

In many ways, 2015 has become a perfect storm for acquisitions, mergers, and consolidation among major suppliers, which are seeing sales slow in their existing market segments and need to broaden their businesses to stay in favor with investors. Rising costs of product development and advanced technologies are also driving the need to become bigger and grow sales at higher rates in the second half of this decade. The emergence of the huge market potential for the Internet of Things (IoT) is causing major IC suppliers to reset their strategies and quickly fill in missing pieces in their product portfolios. China’s ambitious goal to become self-sufficient in semiconductors and reduce imports of ICs from foreign suppliers has also launched a number of acquisitions by Chinese companies and investment groups.

IC Insights believes that the increasing number of mergers and acquisitions, leading to fewer major IC manufacturers and suppliers, is one of major changes in the supply base that illustrate the maturing of the industry. In addition to the monstrous M&A wave currently taking place, trends such as the lack of any new entry points for startup IC manufacturers, the strong movement to the fab-lite business model, and the declining capex as a percent of sales ratio, all promise to dramatically reshape the semiconductor industry landscape over the next five years.

Nanowires could be the LEDs of the future

June 25, 2015

The latest research from the Niels Bohr Institute shows that LEDs made from nanowires will use less energy and provide better light. The researchers studied nanowires using X-ray microscopy and with this method they can pinpoint exactly how the nanowire should be designed to give the best properties. The results are published in the scientific journal, ACS Nano.

Nanowires are very small – about 2 micrometers high (1 micrometer is a thousandth of a millimetre) and 10-500 nanometers in diameter (1 nanometer is a thousandth of a micrometer). Nanowires for LEDs are made up of an inner core of gallium nitride (GaN) and a layer of indium-gallium-nitride (InGaN) on the outside, both of which are semiconducting materials.

“The light in such a diode is dependent on the mechanical strain that exists between the two materials and the strain is very dependent on how the two layers are in contact with each other. We have examined a number of nanowires using X-ray microscopy and even though the nanowires should in principle be identical, we can see that they are different and have very different structure,” explains Robert Feidenhans’l, professor and head of the Niels Bohr Institute at the University of Copenhagen.

The X-ray images of each nanowire show the distribution of the scattering intensity and the mechanical strain in the core of gallium-nitride and the shell of indium-gallium-nitride. The strain shows that the shell fits perfectly with the core.
Credit: Tomas Stankevic, Niels Bohr Institute, University of Copenhagen.

Surprisingly efficient

The studies were performed using nanoscale X-ray microscopy in the electron synchrotron at DESY in Hamburg, Germany. The method is usually very time consuming and the results are often limited to very few or even a single study subject. But here researchers have managed to measure a series of upright nanowires all at once using a special design of a nanofocused X-ray without destroying the nanowires in the process.

“We measured 20 nanowires and when we saw the images, we were very surprised because you could clearly see the details of each nanowire. You can see the structure of both the inner core and the outer layer. If there are defects in the structure or if they are slightly bent, they do not function as well. So we can identify exactly which nanowires are the best and have the most efficient core/shell structure,” explains Tomas Stankevic, a PhD student in the research group ‘Neutron and X-ray Scattering’ at the Niels Bohr Institute at the University of Copenhagen.

The nanowires are produced by a company in Sweden and this new information can be used to tweak the layer structure in the nanowires. Professor Robert Feidenhans’l explains that there is great potential in such nanowires. They will provide a more natural light in LEDs and they will use much less power. In addition, they could be used in smart phones, televisions and many forms of lighting.

The researchers expect that things could go very quickly and that they may already be in use within five years.

IHS says Moore’s Law led to trillions of dollars added to global economy

June 19, 2015

From connectivity to globalization and sustainability, the “Law” created by Gordon Moore’s prediction for the pace of semiconductor technology advances has set the stage for global technology innovation and contribution for 50 years. The exponential advances predicted by Moore’s Law have transformed the world we live in. The ongoing innovation, invention and investment in technology and the effects that arise from it are likely to enable continued advances along this same path in the future, according to a new report from IHS Inc. Titled “Celebrating the 50th Anniversary of Moore’s Law,” the report describes how the activity predicted by Moore’s Law not only drives technological change, but has also created huge economic value and driven social advancement.

In April of 1965, Fairchild Semiconductor’s Research and Development Director, Gordon Moore, who later founded Intel, penned an article that led with the observation that transistors would decrease in cost and increase in performance at an exponential rate. More specifically, Moore posited that the quantity of transistors that can be incorporated into a single chip would approximately double every 18 to 24 months. This seminal observation was later dubbed “Moore’s Law.”

“Fifty years ago today, Moore defined the trajectory of the semiconductor industry, with profound consequences that continue to touch every aspect of our day-to-day lives,” said Dale Ford, vice president and chief analyst for IHS Technology. “In fact, Moore’s Law forecast a period of explosive growth in innovation that has transformed life as we know it.”

The IHS Technology report, which is available as a free download, finds that an estimated $3 trillion of additional value has been added to the global gross domestic product (GDP), plus another $9 trillion of indirect value in the last 20 years, due to the pace of innovation predicted by Moore’s Law. The total value is more than the combined GDP of France, Germany, Italy and the United Kingdom.

If the cadence of Moore’s Law had slowed to every three years, rather than two years, technology would have only advanced to 1998 levels: smart phones would be nine years away, the commercial Internet in its infancy (five years old) and social media would not yet have skyrocketed.

“Moore’s Law has proven to be the most effective predictive tool of the last half-century of technological innovation, economic advancement, and by association, social and cultural change,” Ford said. “It has implications for connectivity and the way we interact, as evidenced by the way social relationships now span the globe. It also provides insight into globalization and economic growth, as technology continues to transform entire industries and economies. Finally it reveals the importance of how sustainability affects life on Earth, as we continue to transform our physical world in both positive and negative ways.”

The Moore’s Law Era: Explosive Economic and Societal Change

The consequences of Moore’s Law has fueled multifactor productivity growth. The activity forecast by the law has contributed a full percentage point to real GDP growth, including both direct and indirect impact, every year between 1995 and 2011, representing 37 percent of global economic impact.

“Not even Gordon Moore himself predicted the blistering pace of change for the modern world,” Ford said. “While it is true most people have never seen a microprocessor, every day we benefit from experiences that are all made possible by the exponential growth in technologies that underpin modern life.”

According to the “Moore’s Law Impact Report,” the repercussions of Moore’s Law have contributed to an improved quality of life, because of the advances made possible in healthcare, sustainability and other industries. The results of advanced digital technology include the following:

Forty percent of the world’s households now have high-speed connections, compared to less than 0.1 percent in 1991
Up to 150 billion incremental barrels of oil could potentially be extracted from discovered global oil fields
Researchers can perform 1.5 million high-speed screening tests per week (up from 180 in 1997), allowing for the development of new material, such as bio-fuels and feedstock’s for plant-based chemicals

Moore’s Law: Reflecting the Pace of Change

Moore’s Law is not a law but an unspoken agreement between the electronics industry and the world economy that inspires engineers, inventors and entrepreneurs to think about what may be possible.

“Whatever has been done, can be outdone,” said Gordon Moore. “The industry has been phenomenally creative in continuing to increase the complexity of chips. It’s hard to believe – at least it’s hard for me to believe – that now we talk in terms of billions of transistors on a chip rather than tens, hundreds or thousands.”

Moore’s observation has transformed computing from a rare, expensive capability into an affordable, pervasive and powerful force – the foundation for Internet, social media, modern data analytics and more. “Moore’s Law has helped inspire invention, giving the world more powerful computers and devices that enable us to connect to each other, to be creative, to be productive, to learn and stay informed, to manage health and finances, and to be entertained,” Ford said.

Millennials: The Stewards of Moore’s Law

From the changing shape and feel of how humans communicate to the delivery of healthcare, changing modes of transportation, cities of the future, harvesting energy resources, classroom learning and more – technology innovations that spring from Moore’s Law likely will remain a foundational force for growth into the next decade.

From data sharing, self-driving cars and drones to smart cities, smart homes and smart agriculture, Moore’s Law will enable people to continuously shrink technology and make it more power efficient, allowing creators, engineers and makers to rethink where – and in what situations – computing is possible and desirable.

Computing may disappear into the objects and spaces that we interact with – even the fabric of our clothes or ingestible tracking devices in our bodies. New devices may be created with powerful, inexpensive technology and combining this with the ability to pool and share more information, new experiences become possible.