Category Archives: LEDs

SEMICON Korea 2015 at COEX in Seoul opens tomorrow with more than 500 exhibiting companies and an expected 40,000 attendees. With the backdrop of Korea as a pacesetter in the industry in memory and DRAM, today’s SEMICON Korea press conference expressed an optimistic lookout, for both 2015 and for longer-term monolithic growth drivers, like the Internet of Things (IoT).

Denny McGuirk, president and CEO of SEMI, summarized recent 2015 semiconductor revenue forecasts, which ranged from IDC’s 3.6 percent to VLSI’s 7.8 percent (IC only). 2015 semiconductor equipment revenue forecasts varied from Gartner forecasting an increase of 5.6 percent to the 15.0 percent growth SEMI forecasted in early December, which would see revenues approaching historic 2011 spending levels.  For semiconductor materials, 2015 could also approach 2011 spending levels. McGuirk described silicon cycles moderating with year-to-year volatility becoming more rational within the consolidated industry.

Semiconductor manufacturing in Korea represents the largest region of installed 300mm fab capacity in the world, with much of the capacity targeted towards both advanced NAND Flash and DRAM.  Korea holds 40 percent of the worldwide Memory output, and is the market leader for installed Memory fab capacity.  According to the SEMI World Fab Forecast, DRAM was a significant driver for the 18 percent growth rates for semiconductor equipment in 2014 and is expected to again fuel growth in 2015. While NAND’s pricing and growth moderated, the tight capacity and expansion of DRAM applications and customer diversity roughly doubled the DRAM ASPs in three years.  Mobility continues to be the primary driver for the Memory market and has kept the pressure on scaling and added functionality. In addition, 3D-IC is now coming to fruition as a solution to NAND to ensure the costs continue to scale with size and transistor density.

Korea fab equipment spending (front-end) in 2015 is forecast to be US$7.8 billion, an almost 28 percent increase over 2014.The combined equipment and materials spending outlook for Korea in 2015 will likely top US$14 billion. The semiconductor, semiconductor equipment, and materials supply chain in Korea is developing depth and breadth and becoming a more complete ecosystem.

The LED market remains an important segment for SEMI members, and this market will experience strong double-digit growth in lighting applications over the next several years. Overall LED fab capacity expansion is stabilizing, and many manufactures continue to transition manufacturing to 4-inch diameter sapphire wafers. Similar to the capacity growth trends, spending on LED fab equipment is also stabilizing with 12 percent growth estimated for 2015. 

Keynotes tomorrow at SEMICON Korea will be presented by Samsung Electronics, Intel, and Cisco Systems. Highlights include: Semiconductor Technology Symposium which addresses the global trends and new technologies of the semiconductor manufacturing process; Supplier Search Program; OEM Supplier Search Meeting; Presidents Reception; and International Standards meetings.

SEMICON Korea 2015 is the leading semiconductor technology event to explore the latest market trends and future developments for technology, featuring extensive technical forums, business programs and standards programs. Key sponsors of SEMICON Korea 2015 include Samsung, SK Hynix, and Dongbu HiTek, plus Lam Research, Applied Materials, Wonik IPS, ASE Group, Advantest, Hanmi Semiconductor, and TEL.

The event is co-located with LED Korea 2015, the largest exhibition in the world for LED manufacturing. For more information on the events, visit SEMICON Korea: www.semiconkorea.org and LED Korea: www.led-korea.org.

The Semiconductor Industry Association (SIA), representing U.S. leadership in semiconductor manufacturing and design, today announced that the global semiconductor industry posted record sales totaling $335.8 billion in 2014, an increase of 9.9 percent from the 2013 total of $305.6 billion. Global sales for the month of December 2014 reached $29.1 billion, marking the strongest December on record, while December 2014 sales in the Americas increased 16 percent compared to December 2013. Fourth quarter global sales of $87.4 billion were 9.3 percent higher than the total of $79.9 billion from the fourth quarter of 2013. Total sales for the year exceeded projections from the World Semiconductor Trade Statistics (WSTS) organization’s industry forecast. All monthly sales numbers are compiled by WSTS and represent a three-month moving average.

“The global semiconductor industry posted its highest-ever sales in 2014, topping $335 billion for the first time thanks to broad and sustained growth across nearly all regions and product categories,” said John Neuffer, president and CEO, Semiconductor Industry Association. “The industry now has achieved record sales in two consecutive years and is well-positioned for continued growth in 2015 and beyond.”

Several semiconductor product segments stood out in 2014. Logic was the largest semiconductor category by sales, reaching $91.6 billion in 2014, a 6.6 percent increase compared to 2013. Memory ($79.2 billion) and micro-ICs ($62.1 billion) – a category that includes microprocessors – rounded out the top three segments in terms of sales revenue. Memory was the fastest growing segment, increasing 18.2 percent in 2014. Within memory, DRAM performed particularly well, increasing by 34.7 percent year-over-year. Other fast-growing product segments included power transistors, which reached $11.9 billion in sales for a 16.1 percent annual increase, discretes ($20.2 billion/10.8 percent increase), and analog ($44.4 billion/10.6 percent increase).

Annual sales increased in all four regional markets for the first time since 2010. The Americas market showed particular strength, with sales increasing by 12.7 percent in 2014. Sales were also up in Asia Pacific (11.4 percent), Europe (7.4 percent), and Japan (0.1 percent), marking the first time annual sales in Japan increased since 2010.

“The U.S. market demonstrated particular strength in 2014, posting double-digit growth to lead all regions,” continued Neuffer. “With the new Congress now underway, we urge policymakers to help foster continued growth by enacting policies that promote U.S. innovation and global competitiveness.”

December 2014
Billions
Month-to-Month Sales
Market Last Month Current Month % Change
Americas 6.53 6.73 3.1%
Europe 3.19 3.01 -5.8%
Japan 2.93 2.80 -4.6%
Asia Pacific 17.12 16.59 -3.1%
Total 29.77 29.13 -2.2%
Year-to-Year Sales
Market Last Year Current Month % Change
Americas 5.80 6.73 16.0%
Europe 2.96 3.01 1.6%
Japan 2.93 2.80 -4.4%
Asia Pacific 14.96 16.59 10.9%
Total 26.65 29.13 9.3%
Three-Month-Moving Average Sales
Market Jun/Jul/Aug Sep/Oct/Nov % Change
Americas 6.06 6.73 11.1%
Europe 3.21 3.01 -6.4%
Japan 3.03 2.80 -7.7%
Asia Pacific 16.93 16.59 -2.0%
Total 29.23 29.13 -0.4%

ClassOne Technology, the wet-chemistry semiconductor equipment manufacturer, has announced the acquisition of two complete product lines from Microprocess Technologies. Included in the acquisition are the Microprocess Spin Rinse Dryer (SRD) and Spray Solvent Tool (SST) families — which have become ClassOne’s Trident SRD and SST lines. The news was jointly announced by Byron Exarcos, President of ClassOne, and Charles Brown, President of Microprocess Technologies.

“This acquisition is a natural fit for us, “ said Byron Exarcos. “ClassOne’s fundamental mission is to provide higher performance wet processing equipment at lower cost to the user, just as we’ve done with our Solstice electroplating tools — and that’s exactly what the new Trident SRDs and SSTs deliver.”

“It’s a win-win for us and for the industry,” said Charles Brown. “ClassOne will continue development and enhancement of the products, and they also will be able to make the tools available to a broader worldwide market.

“This acquisition is the culmination of a relationship that’s been in progress for some time with Microprocess Technologies,” said ClassOne CFO Richard Dotson. “Months ago we began with an exclusive sales agreement for the SRD and SST products, and now ClassOne has secured full ownership of both lines. The manufacturing will be moving to our Kalispell facility where ClassOne’s wet processing experience and ongoing product engineering will make these outstanding products even more advanced in the future.”

“ClassOne has been actively seeking opportunities to expand its offerings in high-growth segments of the industry,” said Exarcos. “Some of the emerging technologies such as MEMS, LEDs, power devices and RF are estimated to be growing at double-digit annual rates.”  He explained that in many of those fabs the Spray Solvent Tool is becoming an essential process-of-record tool for metal lift-off, resist strip and more. “In those scenarios Trident tools are being seen as attractive solutions,” said Exarcos, “because they’re able to handle a range of advanced processes at a cost substantially lower than competitive systems.”

Exarcos explained that many of the Trident performance advantages are the result of innovative and elegant design features, such as wrap-around heating to enhance drying, a Deluge spray manifold to improve rinsing and reduce particles, and ClassOne’s powerful new Solaris system controller.

If you can’t find the ideal material, then design a new one.

Northwestern University’s James Rondinelli uses quantum mechanical calculations to predict and design the properties of new materials by working at the atom-level. His group’s latest achievement is the discovery of a novel way to control the electronic band gap in complex oxide materials without changing the material’s overall composition. The finding could potentially lead to better electro-optical devices, such as lasers, and new energy-generation and conversion materials, including more absorbent solar cells and the improved conversion of sunlight into chemical fuels through photoelectrocatalysis.

“There really aren’t any perfect materials to collect the sun’s light,” said Rondinelli, assistant professor of materials science and engineering in the McCormick School of Engineering. “So, as materials scientists, we’re trying to engineer one from the bottom up. We try to understand the structure of a material, the manner in which the atoms are arranged, and how that ‘genome’ supports a material’s properties and functionality.”

The electronic band gap is a fundamental material parameter required for controlling light harvesting, conversion, and transport technologies. Via band-gap engineering, scientists can change what portion of the solar spectrum can be absorbed by a solar cell, which requires changing the structure or chemistry of the material.

Current tuning methods in non-oxide semiconductors are only able to change the band gap by approximately one electronvolt, which still requires the material’s chemical composition to become altered. Rondinelli’s method can change the band gap by up to 200 percent without modifying the material’s chemistry. The naturally occurring layers contained in complex oxide materials inspired his team to investigate how to control the layers. They found that by controlling the interactions between neutral and electrically charged planes of atoms in the oxide, they could achieve much greater variation in electronic band gap tunability.

“You could actually cleave the crystal and, at the nanometer scale, see well-defined layers that comprise the structure,” he said. “The way in which you order the cations on these layers in the structure at the atomic level is what gives you a new control parameter that doesn’t exist normally in traditional semiconductor materials.”

By tuning the arrangement of the cations–ions having a net positive, neutral, or negative charge–on these planes in proximity to each other, Rondinelli’s team demonstrated a band gap variation of more than two electronvolts. “We changed the band gap by a large amount without changing the material’s chemical formula,” he said. “The only difference is the way we sequenced the ‘genes’ of the material.”

Supported by DARPA and the US Department of Energy, the research is described in the paper “Massive band gap variation in layered oxides through cation ordering,” published in the January 30 issue of Nature Communications. Prasanna Balachandran of Los Alamos National Laboratory in New Mexico is coauthor of the paper.

Arranging oxide layers differently gives rise to different properties. Rondinelli said that having the ability to experimentally control layer-by-layer ordering today could allow researchers to design new materials with specific properties and purposes. The next step is to test his computational findings experimentally.

Rondinelli’s research is aligned with President Barack Obama’s Materials Genome Initiative, which aims to accelerate the discovery of advanced materials to address challenges in energy, healthcare, and transportation.

“Today it’s possible to create digital materials with atomic level precision,” Rondinelli said. “The space for exploration, however, is enormous. If we understand how the material behavior emerges from building blocks, then we make that challenge surmountable and meet one of the greatest challenges today–functionality by design.”

Scientists are focusing on nanometer-sized crystals for the next generation of solar cells. These nanocrystals have excellent optical properties. Compared with silicon in today’s solar cells, nanocrystals can be designed to absorb a larger fraction of the solar light spectrum. However, the development of nanocrystal-based solar cells is challenging.

“These solar cells contain layers of many individual nano-sized crystals, bound together by a molecular glue. Within this nanocrystal composite, the electrons do not flow as well as needed for commercial applications,” explains Vanessa Wood, Professor of Materials and Device Engineering at ETH Zurich. Until now, the physics of electron transport in this complex material system was not understood so it was impossible to systematically engineer better nanocrystal composites.

Wood and her colleagues conducted an extensive study of nanocrystal solar cells, which they fabricated and characterized in their laboratories at ETH Zurich. They were able to describe the electron transport in these types of cells via a generally applicable physical model for the first time. “Our model is able to explain the impact of changing nanocrystal size, nanocrystal material, or binder molecules on electron transport,” says Wood. The model will give scientists in the research field a better understanding of the physical processes inside nanocrystal solar cells and enable them to improve solar cell efficiency.

Promising outlook thanks to quantum effects

The reason for the enthusiasm of many solar cell researchers for the tiny crystals is that at small dimensions effects of quantum physics come into play that are not observed in bulk semiconductors. One example is that the physical properties of the nanocrystals depend on their size. And because scientists can easily control nanocrystal size in the fabrication process, they are also able to influence the properties of nanocrystal semiconductors and optimize them for solar cells.

One such property that can be influenced by changing nanocrystal size is the amount of sun’s spectrum that can be absorbed by the nanocrystals and converted to electricity by the solar cell. Semiconductors do not absorb the entire sunlight spectrum, but rather only radiation below a certain wavelength, or – in other words – with an energy greater than the so-called band gap energy of the semiconductor. In most semiconductors, this threshold can only be changed by changing the material. However, for nanocrystal composites, the threshold can be changed simply by changing the size of the individual crystals. Thus scientists can select the size of nanocrystals in such a way that they absorb the maximum amount of light from a broad range of the sunlight spectrum.

An additional advantage of nanocrystal semiconductors is that they absorb much more sunlight than traditional semiconductors. For example, the absorption coefficient of lead sulfide nanocrystals, used by the ETH researchers in their experimental work, is several orders of magnitude greater than that of silicon semiconductors, used traditionally as solar cells. Thus, a relatively small amount of material is sufficient for the production of nanocrystal solar cells, making it possible to make very thin, flexible solar cells.

Need for greater efficiency

The new model put forth by the ETH researchers answers a series of previously unresolved questions related to electron transport in nanocrystal composites. For example, until now, no experimental evidence existed to prove that the band gap energy of a nanocrystal composite depends directly on the band gap energy of the individual nanocrystals. “For the first time, we have shown experimentally that this is the case,” says Wood.

Over the past five years, scientists have succeeded in greatly increasing the efficiency of nanocrystal solar cells, yet even in the best of these solar cells just 9 percent of the incident sunlight on the cell is converted into electrical energy. “For us to begin to consider commercial applications, we need to achieve an efficiency of at least 15 percent,” explains Wood. Her group’s work brings researchers one step closer to improving the electron transport and solar cells efficiency.

University of Toronto engineers study first single crystal perovskites for new applications Engineers have shone new light on an emerging family of solar-absorbing materials that could clear the way for cheaper and more efficient solar panels and LEDs.

The materials, called perovskites, are particularly good at absorbing visible light, but had never been thoroughly studied in their purest form: as perfect single crystals.

Using a new technique, researchers grew large, pure perovskite crystals and studied how electrons move through the material as light is converted to electricity.

Led by Professor Ted Sargent of The Edward S. Rogers Sr. Department of Electrical & Computer Engineering at the University of Toronto and Professor Osman Bakr of the King Abdullah University of Science and Technology (KAUST), the team used a combination of laser-based techniques to measure selected properties of the perovskite crystals. By tracking down the rapid motion of electrons in the material, they have been able to determine the diffusion length–how far electrons can travel without getting trapped by imperfections in the material–as well as mobility–how fast the electrons can move through the material. Their work was published this week in the journal Science.

“Our work identifies the bar for the ultimate solar energy-harvesting potential of perovskites,” says Riccardo Comin, a post-doctoral fellow with the Sargent Group. “With these materials it’s been a race to try to get record efficiencies, and our results indicate that progress is slated to continue without slowing down..”

In recent years, perovskite efficiency has soared to certified efficiencies of just over 20 per cent, beginning to approach the present-day performance of commercial-grade silicon-based solar panels mounted in Spanish deserts and on Californian roofs.

“In their efficiency, perovskites are closely approaching conventional materials that have already been commercialized,” says Valerio Adinolfi, a PhD candidate in the Sargent Group and co-first author on the paper. “They have the potential to offer further progress on reducing the cost of solar electricity in light of their convenient manufacturability from a liquid chemical precursor.”

The study has obvious implications for green energy, but may also enable innovations in lighting. Think of a solar panel made of perovskite crystals as a fancy slab of glass: light hits the crystal surface and gets absorbed, exciting electrons in the material. Those electrons travel easily through the crystal to electrical contacts on its underside, where they are collected in the form of electric current. Now imagine the sequence in reverse–power the slab with electricity, inject electrons, and release energy as light. A more efficient electricity-to-light conversion means perovskites could open new frontiers for energy-efficient LEDs.

Parallel work in the Sargent Group focuses on improving nano-engineered solar-absorbing particles called colloidal quantum dots. “Perovskites are great visible-light harvesters, and quantum dots are great for infrared,” says Professor Sargent. “The materials are highly complementary in solar energy harvesting in view of the sun’s broad visible and infrared power spectrum.”

“In future, we will explore the opportunities for stacking together complementary absorbent materials,” says Dr. Comin. “There are very promising prospects for combining perovskite work and quantum dot work for further boosting the efficiency.”

Critical Manufacturing, a supplier of integrated manufacturing execution systems (MES), introduces cmNavigo 4.0, the industry’s first comprehensive MES software with embedded finite scheduling. By tightly unifying scheduling into critical MES functions in a modern, Microsoft-based operations management system, cmNavigo 4.0 software improves on-time delivery, shortens total cycle time, and makes better use of plant resources.

“As margins in global high-technology manufacturing shrink, many manufacturers are finding that their legacy MES systems don’t have the flexibility and functionality to meet the demands of today’s volatile markets. The new scheduling, quality control, warehouse management, and shift handoff capabilities we are announcing today reflect our commitment to provide the most modern and unified MES solution available,” said Francisco Almada-Lobo, CEO, Critical Manufacturing. “This new functionality will help manufacturers improve cost control, better manage inventory, and boost productivity of advanced, discrete production operations.”

New Scheduling Functionality Optimizes Production to Meet Customer Demand

cmNavigo 4.0 scheduling models plant floor resources and defines the role of each in fulfilling a mix of orders in an optimal near-term time frame, driven by customer demand. Schedules can be weighted around multiple production criteria and key performance indicators, such as minimizing delivery delays, maximizing machine loads, and reducing cycle times.

Built on Microsoft application development layers, the new scheduling application integrates with more than 30 extensible MES applications. These provide visibility and traceability, operational efficiency, quality management, factory integration, operations intelligence, and factory management.  The modern architecture empowers operations managers to configure and extend models and define workflows without the need for programming.

Integrating scheduling and other MES functionality so tightly avoids duplication of master data, allows real-time updates across different areas of the plant floor, and eliminates the need to maintain separate interfaces. Other new cmNavigo integrated applications announced today deliver the following capabilities:

  • Lot-based sampling enables automated calendar or time-based sampling of production.
  • Document management provides visualization, control, and approval of shop-floor, operations-related documents.
  • Warehouse management synchronizes exchange of information and material between the warehouse and the plant floor.
  • Durables-tracking  simplifies tracking of durable components such as boards, fixtures, tooling and masks, supporting recipe management, maintenance, exception handling, and data collection.
  • shift logbook enhances both performance and safety by regulating exchange of critical information between shifts.

The new scheduling, sampling, factory management, tracking and logbook features of the software combine to address a wide range of MES needs in semiconductor manufacturingelectronics manufacturing, and medical device manufacturing and other manufacturing industries that might have both high mix and high volume lines. cmNavigo 4.0 software is available now for implementation throughout the world. Critical Manufacturing delivers its solutions through highly acclaimed service teams, skilled in extracting maximum value from complex operations. Expertise covers advanced information technology, business intelligence, migration from legacy MES systems, and greenfield installations.

There will also be a free webcast featuring a case history of an IC substrate manufacturer who is now implementing the new software. The webcast will take place on February 19th at 4:00 GMT (11:00 AM EST).  Register at http://www.criticalmanufacturing.com/en/webinar_201502 or at www.criticalmanufacturing.com.

North America-based manufacturers of semiconductor equipment posted $1.37 billion in orders worldwide in December 2014 (three-month average basis) and a book-to-bill ratio of 0.98, according to the December EMDS Book-to-Bill Report published today by SEMI. A book-to-bill of 0.98 means that $98 worth of orders were received for every $100 of product billed for the month.

The three-month average of worldwide bookings in December 2014 was $1.37 billion. The bookings figure is 12.3 percent higher than the final November 2014 level of $1.22 billion, and is 1.1 percent lower than the December 2013 order level of $1.38 billion.

The three-month average of worldwide billings in December 2014 was $1.39 billion. The billings figure is 17.0 percent higher than the final November 2014 level of $1.19 billion, and is 3.1 percent higher than the December 2013 billings level of $1.35 billion.

“While three-month averages for both bookings and billings increased, billings outpaced bookings slightly, nudging the book-to-bill ratio slightly below parity,” said SEMI president and CEO Denny McGuirk. “2015 equipment spending is forecast to remain on track for annual growth given the current expectations for the overall semiconductor industry.”

The SEMI book-to-bill is a ratio of three-month moving averages of worldwide bookings and billings for North American-based semiconductor equipment manufacturers. Billings and bookings figures are in millions of U.S. dollars.

 

Billings
(3-mo. avg)

Bookings
(3-mo. avg)

Book-to-Bill
July 2014 

$1,319.1

$1,417.1

1.07
August 2014 

$1,293.4

$1,346.1

1.04
September 2014 

$1,256.5

$1,186.2

0.94
October 2014 

$1,184.2

$1,102.3

0.93
November 2014 (final)

$1,189.4

$1,216.8

1.02
December 2014 (prelim)

$1,391.9

$1,366.2

0.98

Source: SEMI, January 2015

Reducing the amount of sunlight that bounces off the surface of solar cells helps maximize the conversion of the sun’s rays to electricity, so manufacturers use coatings to cut down on reflections. Now scientists at the U.S. Department of Energy’s Brookhaven National Laboratory show that etching a nanoscale texture onto the silicon material itself creates an antireflective surface that works as well as state-of-the-art thin-film multilayer coatings.

Their method, described in the journal Nature Communications and submitted for patent protection, has potential for streamlining silicon solar cell production and reducing manufacturing costs. The approach may find additional applications in reducing glare from windows, providing radar camouflage for military equipment, and increasing the brightness of light-emitting diodes.

“For antireflection applications, the idea is to prevent light or radio waves from bouncing at interfaces between materials,” said physicist Charles Black, who led the research at Brookhaven Lab’s Center for Functional Nanomaterials (CFN), a DOE Office of Science User Facility.

Preventing reflections requires controlling an abrupt change in “refractive index,” a property that affects how waves such as light propagate through a material. This occurs at the interface where two materials with very different refractive indices meet, for example at the interface between air and silicon. Adding a coating with an intermediate refractive index at the interface eases the transition between materials and reduces the reflection, Black explained.

“The issue with using such coatings for solar cells,” he said, “is that we’d prefer to fully capture every color of the light spectrum within the device, and we’d like to capture the light irrespective of the direction it comes from. But each color of light couples best with a different antireflection coating, and each coating is optimized for light coming from a particular direction. So you deal with these issues by using multiple antireflection layers. We were interested in looking for a better way.”

For inspiration, the scientists turned to a well-known example of an antireflective surface in nature, the eyes of common moths. The surfaces of their compound eyes have textured patterns made of many tiny “posts,” each smaller than the wavelengths of light. This textured surface improves moths’ nighttime vision, and also prevents the “deer in the headlights” reflecting glow that might allow predators to detect them.

“We set out to recreate moth eye patterns in silicon at even smaller sizes using methods of nanotechnology,” said Atikur Rahman, a postdoctoral fellow working with Black at the CFN and first author of the study.

The scientists started by coating the top surface of a silicon solar cell with a polymer material called a “block copolymer,” which can be made to self-organize into an ordered surface pattern with dimensions measuring only tens of nanometers. The self-assembled pattern served as a template for forming posts in the solar cell like those in the moth eye using a plasma of reactive gases-a technique commonly used in the manufacture of semiconductor electronic circuits.

The resulting surface nanotexture served to gradually change the refractive index to drastically cut down on reflection of many wavelengths of light simultaneously, regardless of the direction of light impinging on the solar cell.

“Adding these nanotextures turned the normally shiny silicon surface absolutely black,” Rahman said.

Solar cells textured in this way outperform those coated with a single antireflective film by about 20 percent, and bring light into the device as well as the best multi-layer-coatings used in the industry.

“We are working to understand whether there are economic advantages to assembling silicon solar cells using our method, compared to other, established processes in the industry,” Black said.

Hidden layer explains better-than-expected performance

One intriguing aspect of the study was that the scientists achieved the antireflective performance by creating nanoposts only half as tall as the required height predicted by a mathematical model describing the effect. So they called upon the expertise of colleagues at the CFN and other Brookhaven scientists to help sort out the mystery.

“This is a powerful advantage of doing research at the CFN-both for us and for academic and industrial researchers coming to use our facilities,” Black said. “We have all these experts around who can help you solve your problems.”

Using a combination of computational modeling, electron microscopy, and surface science, the team deduced that a thin layer of silicon oxide similar to what typically forms when silicon is exposed to air seemed to be having an outsized effect.

“On a flat surface, this layer is so thin that its effect is minimal,” explained Matt Eisaman of Brookhaven’s Sustainable Energy Technologies Department and a professor at Stony Brook University. “But on the nanopatterned surface, with the thin oxide layer surrounding all sides of the nanotexture, the oxide can have a larger effect because it makes up a significant portion of the nanotextured material.”

Said Black, “This ‘hidden’ layer was the key to the extra boost in performance.”

The scientists are now interested in developing their self-assembly based method of nanotexture patterning for other materials, including glass and plastic, for antiglare windows and coatings for solar panels.

Sound waves passing through the air, objects that break a body of water and cause ripples, or shockwaves from earthquakes all are considered “elastic” waves. These waves travel at the surface or through a material without causing any permanent changes to the substance’s makeup. Now, engineering researchers at the University of Missouri have developed a material that has the ability to control these waves, creating possible medical, military and commercial applications with the potential to greatly benefit society.

“Methods of controlling and manipulating subwavelength acoustic and elastic waves have proven elusive and difficult; however, the potential applications–once the methods are refined–are tremendous,” said Guoliang Huang, associate professor of mechanical and aerospace engineering in the College of Engineering at MU. “Our team has developed a material that, if used in the manufacture of new devices, could have the ability to sense sound and elastic waves. By manipulating these waves to our advantage, we would have the ability to create materials that could greatly benefit society–from imaging to military enhancements such as elastic cloaking–the possibilities truly are endless.”

In the past, scientists have used a combination of materials such as metal and rubber to effectively ‘bend’ and control waves. Huang and his team designed a material using a single component: steel. The engineered structural material possesses the ability to control the increase of acoustical or elastic waves. Improvements to broadband signals and super-imaging devices also are possibilities.

The material was made in a single steel sheet using lasers to engrave “chiral,” or geometric microstructure patterns, which are asymmetrical to their mirror images. It’s the first such material to be made out of a single medium. Huang and his team intend to introduce elements they can control that will prove its usefulness in many fields and applications.

“In its current state, the metal is a passive material, meaning we need to introduce other elements that will help us control the elastic waves we send to it,” Huang said. “We’re going to make this material much more active by integrating smart materials like microchips that are controllable. This will give us the ability to effectively ‘tune in’ to any elastic sound or elastic wave frequency and generate the responses we’d like; this manipulation gives us the means to control how it reacts to what’s surrounding it.”

Going forward, Huang said there are numerous possibilities for the material to control elastic waves including super-resolution sensors, acoustic and medical hearing devices, as well as a “superlens” that could significantly advance super-imaging, all thanks to the ability to more directly focus the elastic waves.