Category Archives: MEMS

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

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.

By Dr. Adam He, director of Industry Research and Consulting, SEMI China

In June 2014, the State Council of China issued the “National Guideline for the Development and Promotion of the IC Industry,” to support the domestic semiconductor industry. The document addresses development targets, approaches, and measures. It has echoed strongly across the semiconductor industry and attracted global attention due to the ambitious development targets and sizeable support for a national IC industry investment fund.

What’s new?

(1) The Ambitious Development Target

According to the Guideline, the China IC industry revenue should reach RMB350 billion in 2015, and maintain a CAGR of more than 20 percent through 2020. In other words, 2020 revenues are expected to reach US$143 billion, which is 3.5 times that of the US$40.5 billion in 2013. (Note: China IC Industrial revenue refers to the total IC companies’ sales revenue within China, including IC design companies, foundries, IDMs and OSAT companies.)

SEMI--Adam He--for China article

 

Technical and product targets in each segment of the IC industry are clearly defined in the Guideline. The major targets of each segment are listed below.

  • IC manufacturing: mass production for 32/38 nm process shall be realized by 2015 and 16/14 nm process shall be realized by 2020.
  • IC design: certain key technologies (e.g. mobile smart terminal, network communication) shall approach international first-tier level by 2015, and other strategic technologies shall achieve international leading edge by 2020.
  • IC packaging and test: revenue from mid-end to high-end technologies shall be more than 30% of total revenue by 2015, and key technologies shall achieve international leading edge by 2020.
  • Material: 12-inch silicon wafers produced in China shall be ready for use in device production by 2015, and enter global supply chain by 2020.
  • Equipment: 65-45nm key equipment manufactured in China shall be used into production line by 2015, and enter global supply chain by 2020.

(2) National IC Industry Investment Fund Establishment

The manner of industry support has markedly changed from previous policies. The new policy will be adopted with a market-based approach and implemented through national IC industry investment funds to support industry development.

As of December 16, 2014, the latest information indicates that ordinary share-raising for a national IC industry investment fund has been completed and RMB 98.72 billion (US$ 15.9 billion) has been raised. Preferred shares amounting to RMB 40 billion (US$ 6.5 billion) will be further issued in the first quarter of 2015, accumulating to more than RMB130 billion (US$ 21 billion).

Meanwhile, local IC industry investment funds have been established by the cities of Beijing, Shanghai, Wuhan, and Hefei. Of these, Beijing took the lead in establishing a fund in June 2014, totaling RMB 30 billion (US$ 4.8 billion). It is structured as a “fund of funds” and two sub-funds. One sub-fund, supporting for IC manufacturing and semiconductor equipment, is managed by CGP Investment (the “fund of funds” is also managed by CGP); the other sub-fund, supporting IC design and packaging, is managed by Hua Capital.  In addition, the Shanghai IC industry fund, named Shanghai Summitview Capital IC information industry merger fund, totaling RMB10 billion (US$ 1.6 billion) was established in November 2014.

The total government funds are estimated to reach to US$100 billion with the implementation of local industry funds.

What will happen?

It is anticipated that the new policies will exert a significant influence on the semiconductor ecosystem in China.

China’s semiconductor industry will be dramatically expanded given the scale of industry equity funds that are leveraged by government investments. The existing semiconductor industry in China is estimated to have more than 10 percent of global fab capacity and more than 20 percent of global packaging capacity. The new investments will contribute to a powerful expansion in China-based capacity and create a stronger and more globally prominent semiconductor industry in China.

Secondly, the investment and merger activity in the semiconductor industry in China has been very dynamic and will continue to be so with the new investment funds. These newly established national and local IC industry investment funds will not only directly focus on the Fab and IC design companies, but also stimulate the IC industry merger and acquisition activity in and outside of China. For example, shortly after its establishment, Hua Capital (the investment company of IC design and packaging sub-fund of Beijing IC industry fund) proposed to buy Omnivision with Shanghai Pudong Science and Technology Investment Co. Ltd.

In addition, the new policies will also promote marketization development and global cooperation beyond previously implemented investment activities. In the 1990s, the Chinese government established two semiconductor production lines directly through National Engineering Project 908 and 909. In the beginning of the 21st century, SMIC was co-established by state-owned enterprises and an entrepreneurial team. Now, relying on the new capital, the Chinese government is going to support the industry development through equity funds, which is in line with the marketization reform philosophy of the new government and places investors and entrepreneurs at center stage in implementing industry growth. Experienced investors and entrepreneurs with international vision will lead China’s semiconductor industry to a broader global cooperation.

How should international companies respond?

China IC industry investment funds will likely drive market share gains for China players and also more buyout offers from China. Therefore, it is increasingly critical for international companies to consider their strategy and cooperation objectives with China’s semiconductor industry in the light of a huge application market and a dynamic industry ecosystem.

The first step is to better understand China. Companies need to recognize that China is not only the largest semiconductor market — and not just a manufacturing base with a cost advantage. The most important point is that China’s economy and semiconductor industry is changing dramatically, and this will affect the global semiconductor industry ecosystem. Second, China is a diversified economic body, with the developed metropolitan areas such as Shanghai, Beijing and Shenzhen, and the to-be-developed middle and west regions.  Each of these regions will offer specific opportunities for companies in the semiconductor supply chain.

To participate in China’s industry ecosystem, it is essential to establish connections with the stakeholders in China, such as government, customers, suppliers, and even competitors, and to seek opportunities in cooperation and development through mutual understanding and engagement.

During SEMICON China 2015 (March 17-19), SEMI China will host the Tech Investment Forum-China 2015 on March 18. The Tech Investment Forum has already become an important platform between investment and pan-semiconductor industry in China. This year, Mr. Wenwu Ding, the CEO of China National IC Investment Fund will give a keynote speech. There will also be a session where startup companies can pitch to venture investors for project funding.

SEMI China’s Industry Research and Consulting team provides market research, supply chain surveys, investment site evaluations, and partner matching services (visit www.semi.org.cn/marketinfor/exclusive.aspx) or visit the SEMI Industry Research and Statistics website at www.semi.org/en/MarketInfo.

Propelled by the arrival of the Apple Watch, the global market for wireless power and charging in wearable applications is set to attain a gargantuan 3,000 percent expansion this year compared to 2014, according to IHS Technology.

Global revenue this year from shipments of wireless power receivers and transmitters in wearable applications will surge to more than $480 million, up from just $15 million last year, as shown in the attached figure. By 2019, wireless charging in wearables will generate revenue exceeding $1 billion.

“Growth this year will be remarkable for wireless charging in wearable electronic devices, even if in reality the overall penetration of wireless charging into wearables is relatively low given the billions of wearables  that are shipped into the consumer market every year,” said Vicky Yussuff, analyst for wireless charging at IHS Technology. “Still, interest in the use of wireless charging remains high on the part of wearable technology providers and device original equipment manufacturers. As a result, penetration is expected to escalate rapidly over the next five years.”

Apple Watch to spark growth 

In particular, 2015 is anticipated to be an important year for wearable electronics with many of the leading consumer electronics suppliers introducing wireless charging in their products, including smartwatches.

The highest-profile example is the Apple Watch. The smartwatch will ship with Apple’s proprietary MagSafe inductive charging solution, and is expected for release by the end of the second quarter this year. While Apple’s announcement at the end of 2014 did not really promote the benefits that wireless charging technology has to offer, the product is still expected to drive some awareness of wireless charging. Of the total number of wireless-charging-enabled receiver devices forecast to be shipped in wearable electronics in 2015, Apple Watch is projected to take a dominant share, accounting for more than 70 percent of total revenue in wireless-charging-enabled wearable devices.

At present, wireless charging solutions typically consist of a pad or mat on which consumers can place an enabled device for charging, without having to connect the device and the pad or mat physically. The enabled device, such as a smartwatch, can be picked up for use and replaced for charging—often termed “drop and charge.” However, advancements are also taking place in wireless charging technology, and even more versatile solutions are emerging offering greater spatial freedom, including wireless charging through surfaces like a desk, support for wireless charging of multiple devices from the same wireless charger and even wireless charging over distances.

Apple’s solution for the Apple Watch, which uses inductive charging, is not a “drop and charge” mechanism, nor does it offer any range of freedom of movement to the user. In essence, the smartwatch is physically tethered to the charger at all times while charging and being held in place by a magnet. But IHS projects that by the end of 2017, shipments of wearable-technology wireless charging receivers that allow charging over distances will overtake inductive or tightly coupled solutions.

These findings are contained in the report, “Wireless Charging in Wearable Technology Report – 2015,” from the Wireless Power Intelligence Service at IHS.  The IHS report, now available for service subscribers, includes an analysis of opportunities for wireless charging in wearable electronics across key applications and products with forecasts through 2018.

2015-01-13_Wireless_Charging

Leading industry experts provide their perspectives on what to expect in 2015. 3D devices and 3D integration, rising process complexity and “big data” are among the hot topics.

Entering the 3D era

Ghanayem_SSteve Ghanayem, vice president, general manager, Transistor and Interconnect Group, Applied Materials

This year, the semiconductor industry celebrates the 50th anniversary of Moore’s Law. We are at the onset of the 3D era. We expect to see broad adoption of 3D FinFETs in logic and foundry. Investments in 3D NAND manufacturing are expanding as this technology takes hold. This historic 3D transformation impacting both logic and memory devices underscores the aggressive pace of technology innovation in the age of mobility. The benefits of going 3D — lower power consumption, increased processing performance, denser storage capacity and smaller form factors — are essential for the industry to enable new mobility, connectivity and Internet of Things applications.

The semiconductor equipment industry plays a major role in enabling this 3D transformation through new materials, capabilities and processes. Fabricating leading-edge 3D FinFET and NAND devices adds complexity in chip manufacturing that has soared with each node transition. The 3D structure poses unique challenges for deposition, etch, planarization, materials modification and selective processes to create a yielding device, requiring significant innovations in critical dimension control, structural integrity and interface preparation. As chips get smaller and more complex, variations accumulate while process tolerances shrink, eroding performance and yields. Chipmakers need cost-effective solutions to rapidly ramp device yield to maintain the cadence of Moore’s Law. Given these challenges, 2015 will be the year when precision materials engineering technologies are put to the test to demonstrate high-volume manufacturing capabilities for 3D devices.

Achieving excellent device performance and yield for 3D devices demands equipment engineering expertise leveraging decades of knowledge to deliver the optimal system architecture with wide process window. Process technology innovation and new materials with atomic-scale precision are vital for transistor, interconnect and patterning applications. For instance, transistor fabrication requires precise control of fin width, limiting variation from etching to lithography. Contact formation requires precision metal film deposition and atomic-level interface control, critical to lowering contact resistance. In interconnect, new materials such as cobalt are needed to improve gap fill and reliability of narrow lines as density increases with each technology node. Looking forward, these precision materials engineering technologies will be the foundation for continued materials-enabled scaling for many years to come.

Increasing process complexity and opportunities for innovation

trafasBrian Trafas, Chief Marketing Officer, KLA-Tencor Corporation

The 2014 calendar year started with promise and optimism for the semiconductor industry, and it concluded with similar sentiments. While the concern of financial risk and industry consolidation interjects itself at times to overshadow the industry, there is much to be positive about as we arrive in the new year. From increases in equipment spending and revenue in the materials market, to record level silicon wafer shipments projections, 2015 forecasts all point in the right direction. Industry players are also doing their part to address new challenges, creating strategies to overcome complexities associated with innovative techniques, such as multipatterning and 3D architectures.

The semiconductor industry continues to explore new technologies, including 3DIC, TSV, and FinFETs, which carry challenges that also happen to represent opportunities. First, for memory as well as foundry logic, the need for multipatterning to extend lithography is a key focus. We’re seeing some of the value of a traditional lithography tool shifting into some of the non-litho processing steps. As such, customers need to monitor litho and non-litho sources of error and critical defects to be able to yield successfully at next generation nodes.  To enable successful yields with decreasing patterning process windows, it is essential to address all sources of error to provide feed forward and feed backward correctly.

The transition from 2D to 3D in memory and logic is another focus area.  3D leads to tighter process margins because of the added steps and complexity.  Addressing specific yield issues associated with 3D is a great opportunity for companies that can provide value in addressing the challenges customers are facing with these unique architectures.

The wearable, intelligent mobile and IoT markets are continuing to grow rapidly and bring new opportunities. We expect the IoT will drive higher levels of semiconductor content and contribute to future growth in the industry. The demand for these types of devices will add to the entire value chain including semiconductor devices but also software and services.  The semiconductor content in these devices can provide growth opportunities for microcontrollers and embedded processors as well sensing semiconductor devices.

Critical to our industry’s success is tight collaboration among peers and with customers. With such complexity to the market and IC technology, it is very important to work together to understand challenges and identify where there are opportunities to provide value to customers, ultimately helping them to make the right investments and meet their ramps.

Controlling manufacturing variability key to success at 10nm

Rick_Gottscho_Lam_ResearchRichard Gottscho, Ph.D., Executive Vice President, Global Products, Lam Research Corporation 

This year, the semiconductor industry should see the emergence of chip-making at the 10nm technology node. When building devices with geometries this small, controlling manufacturing process variability is essential and most challenging since variation tolerance scales with device dimensions.

Controlling variability has always been important for improving yield and device performance. With every advance in technology and change in design rule, tighter process controls are needed to achieve these benefits. At the 22/20nm technology node, for instance, variation tolerance for CDs (critical dimensions) can be as small as one nanometer, or about 14 atomic layers; for the 10nm node, it can be less than 0.5nm, or just 3 – 4 atomic layers. Innovations that drive continuous scaling to sub-20nm nodes, such as 3D FinFET devices and double/quadruple patterning schemes, add to the challenge of reducing variability. For example, multiple patterning processes require more stringent control of each step because additional process steps are needed to create the initial mask:  more steps mean more variability overall. Multiple patterning puts greater constraints not only on lithography, but also on deposition and etching.

Three types of process variation must be addressed:  within each die or integrated circuit at an atomic level, from die to die (across the wafer), and from wafer to wafer (within a lot, lot to lot, chamber to chamber, and fab to fab). At the device level, controlling CD variation to within a few atoms will increasingly require the application of technologies such as atomic layer deposition (ALD) and atomic layer etching (ALE). Historically, some of these processes were deemed too slow for commercial production. Fortunately, we now have cost-effective solutions, and they are finding their way into volume manufacturing.

To complement these capabilities, advanced process control (APC) will be incorporated into systems to tune chemical and electrical gradients across the wafer, further reducing die-to-die variation. In addition, chamber matching has never been more important. Big data analytics and subsystem diagnostics are being developed and deployed to ensure that every system in a fab produces wafers with the same process results to atomic precision.

Looking ahead, we expect these new capabilities for advanced variability control to move into production environments sometime this year, enabling 10nm-node device fabrication.

2015: The year 3D-IC integration finally comes of age

SONY DSCPaul Lindner, Executive Technology Director, EV Group

2015 will mark an important turning point in the course of 3D-IC technology adoption, as the semiconductor industry moves 3D-IC fully out of development and prototyping stages onto the production floor. In several applications, this transition is already taking place. To date, at least a dozen components in a typical smart phone employing 3D-IC manufacturing technologies. While the application processor and memory in these smart devices continue to be stacked at a package level (POP), many other device components—including image sensors, MEMS, RF front end and filter devices—are now realizing the promise of 3D-IC, namely reduced form factor, increased performance and most importantly reduced manufacturing cost.

The increasing adoption of wearable mobile consumer products will also accelerate the need for higher density integration and reduced form factor, particularly with respect to MEMS devices. More functionality will be integrated both within the same device as well as within one package via 3D stacking. Nine-axis international measurement units (IMUs, which comprise three accelerometers, three gyroscopes and three magnetic axes) will see reductions in size, cost, power consumption and ease of integration.

On the other side of the data stream at data centers, expect to see new developments around 3D-IC technology coming to market in 2015 as well. Compound semiconductors integrated with photonics and CMOS will trigger the replacement of copper wiring with optical fibers to drive down power consumption and electricity costs, thanks to 3D stacking technologies. The recent introduction of stacked DRAM with high-performance microprocessors, such as Intel’s Knights Landing processor, already demonstrate how 3D-IC technology is finally delivering on its promises across many different applications.

Across these various applications that are integrating stacked 3D-IC architectures, wafer bonding will play a key role. This is true for 3D-ICs integrating through silicon vias (TSVs), where temporary bonding in the manufacturing flow or permanent bonding at the wafer-level is essential. It’s the case for reducing power consumption in wearable products integrating MEMS devices, where encapsulating higher vacuum levels will enable low-power operation of gyroscopes. Finally, wafer-level hybrid fusion bonding—a technology that permanently connects wafers both mechanically and electrically in a single process step and supports the development of thinner devices by eliminating adhesive thickness and the need for bumps and pillars—is one of the promising new processes that we expect to see utilized in device manufacturing starting in 2015.

2015: Curvilinear Shapes Are Coming

Aki_Fujimura_D2S_midresAki Fujimura, CEO, D2S

For the semiconductor industry, 2015 will be the start of one of the most interesting periods in the history of Moore’s Law. For the first time in two decades, the fundamental machine architecture of the mask writer is going to change over the next few years—from Variable Shaped Beam (VSB) to multi-beam. Multi-beam mask writing is likely the final frontier—the technology that will take us to the end of the Moore’s Law era. The write times associated with multi-beam writers are constant regardless of the complexity of the mask patterns, and this changes everything. It will open up a new world of opportunities for complex mask making that make trade-offs between design rules, mask/wafer yields and mask write-times a thing of the past. The upstream effects of this may yet be underappreciated.

While high-volume production of multi-beam mask writing machines may not arrive in time for the 10nm node, the industry is expressing little doubt of its arrival by the 7nm node. Since transitions of this magnitude take several years to successfully permeate through the ecosystem, 2015 is the right time to start preparing for the impact of this change.  Multi-beam mask writing enables the creation of very complex mask shapes (even ideal curvilinear shapes). When used in conjunction with optical proximity correction (OPC), inverse lithography technology (ILT) and pixelated masks, this enables more precise wafer writing with improved process margin.  Improving process margin on both the mask and wafer will allow design rules to be tighter, which will re-activate the transistor-density benefit of Moore’s Law.

The prospect of multi-beam mask writing makes it clear that OPC needs to yield better wafer quality by taking advantage of complex mask shapes. This clear direction for the future and the need for more process margin and overlay accuracy at the 10nm node aligns to require complex mask shapes at 10nm. Technologies such as model-based mask data preparation (MB-MDP) will take center stage in 2015 as a bridge to 10nm using VSB mask writing.

Whether for VSB mask writing or for multi-beam mask writing, the shapes we need to write on masks are increasingly complex, increasingly curvilinear, and smaller in minimum width and space. The overwhelming trend in mask data preparation is the shift from deterministic, rule-based, geometric, context-independent, shape-modulated, rectangular processing to statistical, simulation-based, context-dependent, dose- and shape-modulated, any-shape processing. We will all be witnesses to the start of this fundamental change as 2015 unfolds. It will be a very exciting time indeed.

Data integration and advanced packaging driving growth in 2015

mike_plisinski_hiMike Plisinski, Chief Operating Officer, Rudolph Technologies, Inc.

We see two important trends that we expect to have major impact in 2015. The first is a continuing investment in developing and implementing 3D integration and advanced packaging processes, driven not only by the demand for more power and functionality in smaller volumes, but also by the dramatic escalation in the number and density I/O lines per die. This includes not only through silicon vias, but also copper pillar bumps, fan-out packaging, hyper-efficient panel-based packaging processes that use dedicated lithography system on rectangular substrates. As the back end adopts and adapts processes from the front end, the lines that have traditionally separated these areas are blurring. Advanced packaging processes require significantly more inspection and control than conventional packaging and this trend is still only in its early stages.

The other trend has a broader impact on the market as a whole. As consumer electronics becomes a more predominant driver of our industry, manufacturers are under increasing pressure to ramp new products faster and at higher volumes than ever before. Winning or losing an order from a mega cell phone manufacturer can make or break a year, and those orders are being won based on technology and quality, not only price as in the past. This is forcing manufacturers to look for more comprehensive solutions to their process challenges. Instead of buying a tool that meets certain criteria of their established infrastructure, then getting IT to connect it and interpret the data and write the charts and reports for the process engineers so they can use the tool, manufacturers are now pushing much of this onto their vendors, saying, “We want you to provide a working tool that’s going to meet these specs right away and provide us the information we need to adjust and control our process going forward.” They want information, not just data.

Rudolph has made, and will continue to make, major investments in the development of automated analytics for process data. Now more than ever, when our customer buys a system from us, whatever its application – lithography, metrology, inspection or something new, they also want to correlate the data it generates with data from other tools across the process in order to provide more information about process adjustments. We expect these same customer demands to drive a new wave of collaboration among vendors, and we welcome the opportunity to work together to provide more comprehensive solutions for the benefit of our mutual customers.

Process Data – From Famine to Feast

Jack Hager Head ShotJack Hager, Product Marketing Manager, FEI

As shrinking device sizes have forced manufacturers to move from SEM to TEM for analysis and measurement of critical features, process and integration engineers have often found themselves having to make critical decisions using meagre rations of process data. Recent advances in automated TEM sample preparation, using FIBs to prepare high quality, ultra-thin site-specific samples, have opened the tap on the flow of data. Engineers can now make statistically-sound decisions in an environment of abundant data. The availability of fast, high-quality TEM data has whet their appetites for even more data, and the resulting demand is drawing sample preparation systems, and in some cases, TEMs, out of remote laboratories and onto the fab floor or in a “near-line” location. With the high degree of automation of both the sample preparation and TEM, the process engineers, who ultimately consume the data, can now own and operate the systems that generate this data, thus having control over the amount of data created.

The proliferation of exotic materials and new 3D architectures at the most advanced nodes has dramatically increased the need for fast, accurate process data. The days when performance improvements required no more than a relatively simple “shrink” of basically 2D designs using well-understood processes are long gone. Complex, new processes require additional monitoring to aide in process control and failure analysis troubleshooting. Defects, both electrical and physical, are not only more numerous, but typically smaller and more varied. These defects are often buried below the exposed surface which limits traditional inline defect-monitoring equipment effectiveness. This has resulted in renewed challenges in diagnosing their root causes. TEM analysis now plays a more prevalent role providing defect insights that allow actionable process changes.

While process technologies have changed radically, market fundamentals have not. First to market still commands premium prices and builds market share. And time to market is determined largely by the speed with which new manufacturing processes can be developed and ramped to high yields at high volumes. It is in these critical phases of development and ramp that the speed and accuracy of automated sample preparation and TEM analysis is proving most valuable. The methodology has already been adopted by leading manufacturers across the industry – logic and memory, IDM and foundry. We expect the adoption to continue, and with it, the migration of sample preparation and advanced measurement and analytical systems into the fab. 

Diversification of processes, materials will drive integration and customization in sub-fab

Kate Wilson PhotoKate Wilson, Global Applications Director, Edwards

We expect the proliferation of new processes, materials and architectures at the most advanced nodes to drive significant changes in the sub fab where we live. In particular, we expect to see a continuing move toward the integration of vacuum pumping and abatement functions, with custom tuning to optimize performance for the increasingly diverse array of applications becoming a requirement. There is an increased requirement for additional features around the core units such as thermal management, heated N2 injection, and precursor treatment pre- and post-pump that also need to be managed.

Integration offers clear advantages, not only in cost savings but also in safety, speed of installation, smaller footprint, consistent implementation of correct components, optimized set-ups and controlled ownership of the process effluents until they are abated reliably to safe levels. The benefits are not always immediately apparent. Just as effective integration is much more than simply adding a pump to an abatement system, the initial cost of an integrated system is more than the cost of the individual components. The cost benefits in a properly integrated system accrue primarily from increased efficiencies and reliability over the life of the system, and the magnitude of the benefit depends on the complexity of the process. In harsh applications, including deposition processes such as CVD, Epi and ALD, integrated systems provide significant improvements in uptime, service intervals and product lifetimes as well as significant safety benefits.

The trend toward increasing process customization impacts the move toward integration through its requirement that the integrator have detailed knowledge of the process and its by-products. Each manufacturer may use a slightly different recipe and a small change in materials or concentrations can have a large effect on pumping and abatement performance. This variability must be addressed not only in the design of the integrated system but also in tuning its operation during initial commissioning and throughout its lifetime to achieve optimal performance. Successful realization of the benefits of integration will rely heavily on continuing support based on broad application knowledge and experience.

Giga-scale challenges will dominate 2015

Dr. Zhihong Liu

Dr. Zhihong Liu, Executive Chairman, ProPlus Design Solutions, Inc.

It wasn’t all that long ago when nano-scale was the term the semiconductor industry used to describe small transistor sizes to indicate technological advancement. Today, with Moore’s Law slowing down at sub-28nm, the term more often heard is giga-scale due to a leap forward in complexity challenges caused in large measure by the massive amounts of big data now part of all chip design.

Nano-scale technological advancement has enabled giga-sized applications for more varieties of technology platforms, including the most popular mobile, IoT and wearable devices. EDA tools must respond to such a trend. On one side, accurately modeling nano-scale devices, including complex physical effects due to small geometry sizes and complicated device structures, has increased in importance and difficulties. Designers now demand more from foundries and have higher standards for PDK and model accuracies. They need to have a deep understanding of the process platform in order to  make their chip or IP competitive.

On the other side, giga-scale designs require accurate tools to handle increasing design size. The small supply voltage associated with technology advancement and low-power applications, and the impact of various process variation effects, have reduced available design margins. Furthermore, the big circuit size has made the design sensitive to small leakage current and small noise margin. Accuracy will soon become the bottleneck for giga-scale designs.

However, traditional design tools for big designs, such as FastSPICE for simulation and verification, mostly trade-off accuracy for capacity and performance. One particular example will be the need for accurate memory design, e.g., large instance memory characterization, or full-chip timing and power verification. Because embedded memory may occupy more than 50 percent of chip die area, it will have a significant impact on chip performance and power. For advanced designs, power or timing characterization and verification require much higher accuracy than what FastSPICE can offer –– 5 percent or less errors compared to golden SPICE.

To meet the giga-scale challenges outlined above, the next-generation circuit simulator must offer the high accuracy of a traditional SPICE simulator, and have similar capacity and performance advantages of a FastSPICE simulator. New entrants into the giga-scale SPICE simulation market readily handle the latest process technologies, such as 16/14nm FinFET, which adds further challenges to capacity and accuracy.

One giga-scale SPICE simulator can cover small and large block simulations, characterization, or full-chip verifications, with a pure SPICE engine that guarantees accuracy, and eliminates inconsistencies in the traditional design flow.  It can be used as the golden reference for FastSPICE applications, or directly replace FastSPICE for memory designs.

The giga-scale era in chip design is here and giga-scale SPICE simulators are commercially available to meet the need.

University of Wisconsin-Madison materials engineers have made a significant leap toward creating higher-performance electronics with improved battery life — and the ability to flex and stretch.

Led by materials science Associate Professor Michael Arnold and Professor Padma Gopalan, the team has reported the highest-performing carbon nanotube transistors ever demonstrated. In addition to paving the way for improved consumer electronics, this technology could also have specific uses in industrial and military applications.

In a paper published recently in the journal ACS Nano, Arnold, Gopalan and their students reported transistors with an on-off ratio that’s 1,000 times better and a conductance that’s 100 times better than previous state-of-the-art carbon nanotube transistors.

“Carbon nanotubes are very strong and very flexible, so they could also be used to make flexible displays and electronics that can stretch and bend, allowing you to integrate electronics into new places like clothing,” says Arnold. “The advance enables new types of electronics that aren’t possible with the more brittle materials manufacturers are currently using.”

Carbon nanotubes are single atomic sheets of carbon rolled up into a tube. As some of the best electrical conductors ever discovered, carbon nanotubes have long been recognized as a promising material for next-generation transistors, which are semiconductor devices that can act like an on-off switch for current or amplify current. This forms the foundation of an electronic device.

However, researchers have struggled to isolate purely semiconducting carbon nanotubes, which are crucial, because metallic nanotube impurities act like copper wires and “short” the device. Researchers have also struggled to control the placement and alignment of nanotubes. Until now, these two challenges have limited the development of high-performance carbon nanotube transistors.

Building on more than two decades of carbon nanotube research in the field, the UW-Madison team drew on cutting-edge technologies that use polymers to selectively sort out the semiconducting nanotubes, achieving a solution of ultra-high-purity semiconducting carbon nanotubes.

Previous techniques to align the nanotubes resulted in less-than-desirable packing density, or how close the nanotubes are to one another when they are assembled in a film. However, the UW-Madison researchers pioneered a new technique, called floating evaporative self-assembly, or FESA, which they described earlier in 2014 in the ACS journal Langmuir. In that technique, researchers exploited a self-assembly phenomenon triggered by rapidly evaporating a carbon nanotube solution.

The team’s most recent advance also brings the field closer to realizing carbon nanotube transistors as a feasible replacement for silicon transistors in computer chips and in high-frequency communication devices, which are rapidly approaching their physical scaling and performance limits.

“This is not an incremental improvement in performance,” Arnold says. “With these results, we’ve really made a leap in carbon nanotube transistors. Our carbon nanotube transistors are an order of magnitude better in conductance than the best thin film transistor technologies currently being used commercially while still switching on and off like a transistor is supposed to function.”

The researchers have patented their technology through the Wisconsin Alumni Research Foundation and have begun working with companies to accelerate the technology transfer to industry.

Nanoengineers at the University of California, San Diego have tested a temporary tattoo that both extracts and measures the level of glucose in the fluid in between skin cells. This first-ever example of the flexible, easy-to-wear device could be a promising step forward in noninvasive glucose testing for patients with diabetes.

The sensor was developed and tested by graduate student Amay Bandodkar and colleagues in Professor Joseph Wang’s laboratory at the NanoEngineering Department and the Center for Wearable Sensors at the Jacobs School of Engineering at UC San Diego. Bandodkar said this “proof-of-concept” tattoo could pave the way for the Center to explore other uses of the device, such as detecting other important metabolites in the body or delivering medicines through the skin.

Nanoengineers at the University of California, San Diego have tested a temporary tattoo that both extracts and measures the level of glucose in the fluid in between skin cells. CREDIT Jacobs School of Engineering/UC San Diego

Nanoengineers at the University of California, San Diego have tested a temporary tattoo that both extracts and measures the level of glucose in the fluid in between skin cells. CREDIT: Jacobs School of Engineering/UC San Diego

At the moment, the tattoo doesn’t provide the kind of numerical readout that a patient would need to monitor his or her own glucose. But this type of readout is being developed by electrical and computer engineering researchers in the Center for Wearable Sensors. “The readout instrument will also eventually have Bluetooth capabilities to send this information directly to the patient’s doctor in real-time or store data in the cloud,” said Bandodkar.

The research team is also working on ways to make the tattoo last longer while keeping its overall cost down, he noted. “Presently the tattoo sensor can easily survive for a day. These are extremely inexpensive–a few cents–and hence can be replaced without much financial burden on the patient.”

The Center “envisions using these glucose tattoo sensors to continuously monitor glucose levels of large populations as a function of their dietary habits,” Bandodkar said. Data from this wider population could help researchers learn more about the causes and potential prevention of diabetes, which affects hundreds of millions of people and is one of the leading causes of death and disability worldwide.

People with diabetes often must test their glucose levels multiple times per day, using devices that use a tiny needle to extract a small blood sample from a fingertip. Patients who avoid this testing because they find it unpleasant or difficult to perform are at a higher risk for poor health, so researchers have been searching for less invasive ways to monitor glucose.

In their report in the journal Analytical Chemistry, Wang and his co-workers describe their flexible device, which consists of carefully patterned electrodes printed on temporary tattoo paper. A very mild electrical current applied to the skin for 10 minutes forces sodium ions in the fluid between skin cells to migrate toward the tattoo’s electrodes. These ions carry glucose molecules that are also found in the fluid. A sensor built into the tattoo then measures the strength of the electrical charge produced by the glucose to determine a person’s overall glucose levels.

“The concentration of glucose extracted by the non-invasive tattoo device is almost hundred times lower than the corresponding level in the human blood,” Bandodkar explained. “Thus we had to develop a highly sensitive glucose sensor that could detect such low levels of glucose with high selectivity.”

A similar device called GlucoWatch from Cygnus Inc. was marketed in 2002, but the device was discontinued because it caused skin irritation, the UC San Diego researchers note. Their proof-of-concept tattoo sensor avoids this irritation by using a lower electrical current to extract the glucose.

Wang and colleagues applied the tattoo to seven men and women between the ages of 20 and 40 with no history of diabetes. None of the volunteers reported feeling discomfort during the tattoo test, and only a few people reported feeling a mild tingling in the first 10 seconds of the test.

To test how well the tattoo picked up the spike in glucose levels after a meal, the volunteers ate a carb-rich meal of a sandwich and soda in the lab. The device performed just as well at detecting this glucose spike as a traditional finger-stick monitor.

The researchers say the device could be used to measure other important chemicals such as lactate, a metabolite analyzed in athletes to monitor their fitness. The tattoo might also someday be used to test how well a medication is working by monitoring certain protein products in the intercellular fluid, or to detect alcohol or illegal drug consumption.

The SEMI Industry Strategy Symposium (ISS) opened yesterday with the theme “Riding the Wave of Silicon Magic.” The sold-out conference of the industry’s C-level executives highlighted favorable forecasts in the year’s first strategic outlook for the global microelectronics manufacturing industry.  The underlying drivers for growth and the next wave emerging from the Internet of Things (IoT) were discussed from several perspectives.

Opening keynoter Scott McGregor, president and CEO of Broadcom, traced the history of the industry’s more than 50 years of exponential improvements in silicon speed, power and design since Moore’s Law in 1965.  McGregor sees the next wave of Silicon Magic as a $15 trillion opportunity that will provide ubiquitous, nonstop, seamless high-speed connectivity.  Still, McGregor believes that three key issues challenge the industry’s growth.   First, patent reform, as patents are the foundation of the innovation economy and the global patent system does not meet today’s industry realities. Second, interoperability and standards, as IoT is raising the stakes for data privacy and security.  Finally, STEM education, as in the future, all businesses will be tech businesses.

In the Economic Trends session, presenters took on both macroeconomic and detailed industy-specific forecasts:

  • Nariman Behravesh, senior economist at IHS, presented the macroeconomic view of 2015 and the global implications brought on by the sharp drop in oil prices.  IHS predicted that the U.S. will grow in the 2.5-3.0 percent range in 2015 while other regions will be mixed: the European recovery will be slow, Japan’s economy will regain weak momentum, and China growth will continue to slow, but remain stronger than most. 
  • Mario Morales, VP at IDC, presented the 2015 semiconductor outlook. IDC saw the semiconductor market grow 7 percent in 2014 and projects 3.8 percent growth in 2015. Market growth will be led largely by automotive and industrial segments. 
  • Andrea Lati, principle analyst for VLSI Research, presented the 2015 semiconductor equipment outlook.  VLSI saw semiconductor equipment sales coming in at 17 percent growth in 2014 and forecasts 8 percent growth in 2015. VLSI noted the top 7 chipmakers accounted for 71 percent of spending in 2014 (vs. 56 percent in 2010). VLSI sees the consolidation driving an industry that has smaller cyclic peaks and is settling into a moderated two-year cycle cadence with fewer players having less incentive to individually make a market share grab.” 

Several presenters discussed the Internet of Things (IoT) and offered that the IoT provides an unprecedented growth opportunity — and understanding just what IoT is, at this stage, a challenge.  The lively session featured Frank Jones, VP and GM at Intel, David Ashley, VP of Customer Value Chain Management at Cisco Systems, Shawn DuBravac, chief economist and director of research at the Consumer Electronics Association (CEA), and Martin Reynolds, managing VP and fellow at Gartner.

Among the insights in the IoT session, Jones stressed that with all the IoT hype, it’s critical to demonstrate business value. Working with partners, he cited emerging IoT examples such as: saving 43 percent in time with an integrated “Smart Parking Solution” and improvements to Intel’s own factories with fab personnel defining a process step predictive maintenance tool (sensors and analytics) that saved $9 million per year.  Ashley made the point that with $19 trillion for the IoE at stake, the supply chain, including economic trends (labor wage inflation, government policy, shrinking life cycles) and ecosystem (supplier consolidation, visibility, consumer-driven technology) need to be addressed.  DuBravac focused on how everyday objects are becoming smarter and more connected and said that the key to technology should be what is meaningful as opposed to what is possible.

Days 2 and 3 at ISS will delve deeper into the underpinnings of the industry.  Technology and manufacturing insights will be discussed with presentations from:  TSMC, Altera, XMC, Intel, Honeywell, Micron, imec, ASE, IBM, Lux Research, Illumina, Cypress, Boing, and McKinsey.  A “Silicon Magic” panel will wrap up the conference with Intel, Lam Research, JSR, TSMC, and Qualcomm. The SEMI Industry Strategy Symposium (ISS) examines global economic, technology, market, business and geo-political developments influencing the semiconductor industry.

JEOL USA and the University of California’s Irvine Materials Research Institute (IMRI) have entered into a strategic partnership to create a premier electron microscopy and materials science research facility. The IMRI will serve as an interdisciplinary nexus for the study and development of new materials, enabling advances in solar cell, battery, semiconductor, biological science, and medical technologies.

The IMRI is headed by Dr. Xiaoqing Pan, an internationally-recognized researcher in the physics of materials who joined the UC Irvine faculty in 2015 to lead the $20 million initiative.

The new electron microscopy cluster, to be known as the JEOL Center for Nanoscale Solutions, will house JEOL’s highest performing Transmission Electron Microscopes (TEM) for characterizing and analyzing materials to determine their potential for a myriad of advanced applications.

This will be the first research lab in the Americas to install the newly-introduced JEOL Grand ARM, which exceeds atomic resolution boundaries for any commercially-available TEM today. The Grand ARM offers 63 pm resolution at 300 keV for atom-by-atom characterization and chemical mapping. It features JEOL-proprietary spherical aberration correctors integrated in the image-forming system and illumination system, and an ultra-stable cold-cathode field emission electron gun.

The center will also house the high throughput, nano-analysis JEM-2800 TEM/STEM, a versatile microscope favored for its ease of use while maintaining the highest level of performance.  The JEM-2800 features dual large area Silicon Drift Detectors with unprecedented sensitivity for high throughput EDS analysis.

Researchers will also utilize the cryogenic and atomic level structural analysis capabilities of the JEOL JEM-2100F TEM to examine biological materials, large molecules, and medical biopsy samples in efforts to improve delivery of pharmaceuticals to the human body.

“The electron microscopy initiative and the IMRI at UC Irvine will provide new tools and great opportunities for potential collaborations with the many researchers on campus and in southern California,” said Pan.  In his work he has pioneered the development of advanced functional materials and the characterization of their structure-property relationships at the atomic scale, which range from ceramics and semiconductors to biological materials and nanomaterials.

“This foremost facility will be an important resource for some of the most renowned scientists in the world,” said JEOL USA President Peter Genovese.” With the installation of our flagship atomic resolution TEM, the JEOL Center for Nanoscale Solutions will be the most advanced electron microscopy cluster available for probing the atomic structure and properties of materials.”

SUNY Polytechnic Institute (SUNY Poly) yesterday announced the SUNY Board of Trustees has appointed Dr. Alain Kaloyeros as the founding President of SUNY Poly.

“Dr. Alain Kaloyeros has led SUNY’s College of Nanoscale Science and Engineering since its inception, helping to make this first-of-its-kind institution a global model and position New York State as a leader in the nanotechnology-driven economy of the 21st century,” said SUNY Board Chairman H. Carl McCall. “It is only fitting that Dr. Kaloyeros be the one to build that model and bring it to scale through the continued development and expansion of SUNY Polytechnic Institute.”

“As the visionary who built CNSE into a world-class, high-tech, and globally recognized academic and economic development juggernaut, Dr. Alain Kaloyeros is the clear choice to lead SUNY Polytechnic Institute into the future,” said SUNY Chancellor Nancy L. Zimpher. “The unprecedented statewide expansion of the campus’ unique model and continued strong partnership with Governor Andrew Cuomo is testament to SUNY’s promise as New York’s economic engine and stature as an affordable, world-class educational institution. I am confident that, as its president, Dr. Kaloyeros will continue to build on SUNY Poly’s success and contributions to New York.”

“SUNY Polytechnic Institute is a revolutionary discovery and education model with two coequal campuses in Utica and Albany, and a key component of Governor Cuomo’s vision for high-tech innovation, job creation, and economic development in New York State.  I am privileged and humbled to be selected for the honor of leading this world-class institution and its talented and dedicated faculty, staff, and students,” said Dr. Kaloyeros.  “I would like to extend my sincere gratitude to the Governor, Chairman Carl McCall, the SUNY Board of Trustees, and Chancellor Nancy Zimpher for their continued confidence and support.”

Dr. Kaloyeros received his Ph.D. in Experimental Condensed Matter Physics from the University of Illinois at Urbana-Champaign in 1987.  A year later, Governor Mario M. Cuomo recruited Dr. Kaloyeros under the SUNY Graduate Research Initiative.  Since then, Dr. Kaloyeros has been actively involved in the development and implementation of New York’s high-tech strategy to become a global leader in the nanotechnology-driven economy of the 21st Century.

A critical cornerstone of New York’s high-technology strategy has been the establishment of the Colleges of Nanoscale Science and Engineering (CNSE) at SUNY Poly as a truly global resource that enables pioneering research and development, technology deployment, education, and commercialization for the international nanoelectronics industry.  CNSE was originally founded in April 2004 in response to the rapid changes and evolving needs in the educational and research landscapes brought on by the emergence of nanotechnology.  Under Dr. Kaloyeros’ leadership, CNSE has generated over $20B in public and private investments.

In 2014, CNSE merged with the SUNY Institute of Technology to form SUNY Poly, which today represents the world’s most advanced university-driven research enterprise, offering students a one-of-a-kind academic experience and providing over 300 corporate partners with access to an unmatched ecosystem for leading-edge R&D and commercialization of nanoelectronics and nanotechnology innovations.