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IBM announced it is investing $3 billion over the next 5 years in two broad research and early stage development programs to push the limits of chip technology needed to meet the emerging demands of cloud computing and Big Data systems. These investments will push IBM’s semiconductor innovations from today’s breakthroughs into the advanced technology leadership required for the future.

The first research program is aimed at so-called “7 nanometer and beyond” silicon technology that will address serious physical challenges that are threatening current semiconductor scaling techniques and will impede the ability to manufacture such chips. The second is focused on developing alternative technologies for post-silicon era chips using entirely different approaches, which IBM scientists and other experts say are required because of the physical limitations of silicon based semiconductors.

Cloud and big data applications are placing new challenges on systems, just as the underlying chip technology is facing numerous significant physical scaling limits.  Bandwidth to memory, high speed communication and device power consumption are becoming increasingly challenging and critical.

The teams will comprise IBM Research scientists and engineers from Albany and Yorktown, New York; Almaden, California; and Europe. In particular, IBM will be investing significantly in emerging areas of research that are already underway at IBM such as carbon nanoelectronics, silicon photonics, new memory technologies, and architectures that support quantum and cognitive computing.

These teams will focus on providing orders of magnitude improvement in system level performance and energy efficient computing. In addition, IBM will continue to invest in the nanosciences and quantum computing–two areas of fundamental science where IBM has remained a pioneer for over three decades.

7 nanometer technology and beyond
IBM Researchers and other semiconductor experts predict that while challenging, semiconductors show promise to scale from today’s 22 nanometers down to 14 and then 10 nanometers in the next several years.  However, scaling to 7 nanometers and perhaps below, by the end of the decade will require significant investment and innovation in semiconductor architectures as well as invention of new tools and techniques for manufacturing.

“The question is not if we will introduce 7 nanometer technology into manufacturing, but rather how, when, and at what cost?” said John Kelly, senior vice president, IBM Research. “IBM engineers and scientists, along with our partners, are well suited for this challenge and are already working on the materials science and device engineering required to meet the demands of the emerging system requirements for cloud, big data, and cognitive systems. This new investment will ensure that we produce the necessary innovations to meet these challenges.”

“Scaling to 7nm and below is a terrific challenge, calling for deep physics competencies in processing nano materials affinities and characteristics. IBM is one of a very few companies who has repeatedly demonstrated this level of science and engineering expertise,” said Richard Doherty, technology research director, The Envisioneering Group.

Bridge to a “Post-Silicon” Era
Silicon transistors, tiny switches that carry information on a chip, have been made smaller year after year, but they are approaching a point of physical limitation. Their increasingly small dimensions, now reaching the nanoscale, will prohibit any gains in performance due to the nature of silicon and the laws of physics. Within a few more generations, classical scaling and shrinkage will no longer yield the sizable benefits of lower power, lower cost and higher speed processors that the industry has become accustomed to.

With virtually all electronic equipment today built on complementary metal–oxide–semiconductor (CMOS) technology, there is an urgent need for new materials and circuit architecture designs compatible with this engineering process as the technology industry nears physical scalability limits of the silicon transistor.

Beyond 7 nanometers, the challenges dramatically increase, requiring a new kind of material to power systems of the future, and new computing platforms to solve problems that are unsolvable or difficult to solve today. Potential alternatives include new materials such as carbon nanotubes, and non-traditional computational approaches such as neuromorphic computing, cognitive computing, machine learning techniques, and the science behind quantum computing.

As the leader in advanced schemes that point beyond traditional silicon-based computing, IBM holds over 500 patents for technologies that will drive advancements at 7nm and beyond silicon — more than twice the nearest competitor. These continued investments will accelerate the invention and introduction into product development for IBM’s highly differentiated computing systems for cloud, and big data analytics.

Several exploratory research breakthroughs that could lead to major advancements in delivering dramatically smaller, faster and more powerful computer chips, include quantum computing, neurosynaptic computing, silicon photonics, carbon nanotubes, III-V technologies, low power transistors and graphene:

Quantum Computing
The most basic piece of information that a typical computer understands is a bit. Much like a light that can be switched on or off, a bit can have only one of two values: “1” or “0.” Described as superposition, this special property of qubits enables quantum computers to weed through millions of solutions all at once, while desktop PCs would have to consider them one at a time.

IBM is a world leader in superconducting qubit-based quantum computing science and is a pioneer in the field of experimental and theoretical quantum information, fields that are still in the category of fundamental science – but one that, in the long term, may allow the solution of problems that are today either impossible or impractical to solve using conventional machines. The team recently demonstrated the first experimental realization of parity check with three superconducting qubits, an essential building block for one type of quantum computer.

Neurosynaptic Computing
Bringing together nanoscience, neuroscience, and supercomputing, IBM and university partners have developed an end-to-end ecosystem including a novel non-von Neumann architecture, a new programming language, as well as applications. This novel technology allows for computing systems that emulate the brain’s computing efficiency, size and power usage. IBM’s long-term goal is to build a neurosynaptic system with ten billion neurons and a hundred trillion synapses, all while consuming only one kilowatt of power and occupying less than two liters of volume.

Silicon Photonics
IBM has been a pioneer in the area of CMOS integrated silicon photonics for over 12 years, a technology that integrates functions for optical communications on a silicon chip, and the IBM team has recently designed and fabricated the world’s first monolithic silicon photonics based transceiver with wavelength division multiplexing.  Such transceivers will use light to transmit data between different components in a computing system at high data rates, low cost, and in an energetically efficient manner.

Silicon nanophotonics takes advantage of pulses of light for communication rather than traditional copper wiring and provides a super highway for large volumes of data to move at rapid speeds between computer chips in servers, large datacenters, and supercomputers, thus alleviating the limitations of congested data traffic and high-cost traditional interconnects.

Businesses are entering a new era of computing that requires systems to process and analyze, in real-time, huge volumes of information known as Big Data. Silicon nanophotonics technology provides answers to Big Data challenges by seamlessly connecting various parts of large systems, whether few centimeters or few kilometers apart from each other, and move terabytes of data via pulses of light through optical fibers.

III-V technologies
IBM researchers have demonstrated the world’s highest transconductance on a self-aligned III-V channel metal-oxide semiconductor (MOS) field-effect transistors (FETs) device structure that is compatible with CMOS scaling. These materials and structural innovation are expected to pave path for technology scaling at 7nm and beyond.  With more than an order of magnitude higher electron mobility than silicon, integrating III-V materials into CMOS enables higher performance at lower power density, allowing for an extension to power/performance scaling to meet the demands of cloud computing and big data systems.

Carbon Nanotubes
IBM Researchers are working in the area of carbon nanotube (CNT) electronics and exploring whether CNTs can replace silicon beyond the 7 nm node.  As part of its activities for developing carbon nanotube based CMOS VLSI circuits, IBM recently demonstrated — for the first time in the world — 2-way CMOS NAND gates using 50 nm gate length carbon nanotube transistors.

IBM also has demonstrated the capability for purifying carbon nanotubes to 99.99 percent, the highest (verified) purities demonstrated to date, and transistors at 10 nm channel length that show no degradation due to scaling–this is unmatched by any other material system to date.

Carbon nanotubes are single atomic sheets of carbon rolled up into a tube. The carbon nanotubes form the core of a transistor device that will work in a fashion similar to the current silicon transistor, but will be better performing. They could be used to replace the transistors in chips that power data-crunching servers, high performing computers and ultra fast smart phones.

Carbon nanotube transistors can operate as excellent switches at molecular dimensions of less than ten nanometers – the equivalent to 10,000 times thinner than a strand of human hair and less than half the size of the leading silicon technology. Comprehensive modeling of the electronic circuits suggests that about a five to ten times improvement in performance compared to silicon circuits is possible.

Graphene
Graphene is pure carbon in the form of a one atomic layer thick sheet.  It is an excellent conductor of heat and electricity, and it is also remarkably strong and flexible.  Electrons can move in graphene about ten times faster than in commonly used semiconductor materials such as silicon and silicon germanium. Its characteristics offer the possibility to build faster switching transistors than are possible with conventional semiconductors, particularly for applications in the handheld wireless communications business where it will be a more efficient switch than those currently used.

Recently in 2013, IBM demonstrated the world’s first graphene based integrated circuit receiver front end for wireless communications. The circuit consisted of a 2-stage amplifier and a down converter operating at 4.3 GHz.

Next Generation Low Power Transistors
In addition to new materials like CNTs, new architectures and innovative device concepts are required to boost future system performance. Power dissipation is a fundamental challenge for nanoelectronic circuits. To explain the challenge, consider a leaky water faucet — even after closing the valve as far as possible water continues to drip — this is similar to today’s transistor, in that energy is constantly “leaking” or being lost or wasted in the off-state.

A potential alternative to today’s power hungry silicon field effect transistors are so-called steep slope devices. They could operate at much lower voltage and thus dissipate significantly less power. IBM scientists are researching tunnel field effect transistors (TFETs). In this special type of transistors the quantum-mechanical effect of band-to-band tunneling is used to drive the current flow through the transistor. TFETs could achieve a 100-fold power reduction over complementary CMOS transistors, so integrating TFETs with CMOS technology could improve low-power integrated circuits.

Recently, IBM has developed a novel method to integrate III-V nanowires and heterostructures directly on standard silicon substrates and built the first ever InAs/Si tunnel diodes and TFETs using InAs as source and Si as channel with wrap-around gate as steep slope device for low power consumption applications.

“In the next ten years computing hardware systems will be fundamentally different as our scientists and engineers push the limits of semiconductor innovations to explore the post-silicon future,” said Tom Rosamilia, senior vice president, IBM Systems and Technology Group. “IBM Research and Development teams are creating breakthrough innovations that will fuel the next era of computing systems.”

IBM’s contributions to silicon and semiconductor innovation include the invention and/or first implementation of: the single cell DRAM, the “Dennard scaling laws” underpinning “Moore’s Law”, chemically amplified photoresists, copper interconnect wiring, Silicon on Insulator, strained engineering, multi core microprocessors, immersion lithography, high speed silicon germanium (SiGe), High-k gate dielectrics, embedded DRAM, 3D chip stacking, and Air gap insulators.

IBM researchers also are credited with initiating the era of nano devices following the Nobel prize winning invention of the scanning tunneling microscope which enabled nano and atomic scale invention and innovation.

IBM will also continue to fund and collaborate with university researchers to explore and develop the future technologies for the semiconductor industry. In particular, IBM will continue to support and fund university research through private-public partnerships such as the NanoElectornics Research Initiative (NRI), and the Semiconductor Advanced Research Network (STARnet), and the Global Research Consortium (GRC) of the Semiconductor Research Corporation.

 Applied Materials, Inc. and Tokyo Electron Limited today unveiled the new name and logo of their combined company which will be used once the merger closes. Derived from the concept of eternal innovation for society, Eteris [pronounced: eh-TAIR-iss] embodies the spirit of what will drive the new company and speaks to what makes the combination unique.

“The new name for our combined company builds on the strong legacies of Applied Materials and Tokyo Electron, creating something even greater than the sum of the two,” said Tetsuro Higashi, chairman, president and CEO of Tokyo Electron. “At the time we announced our plans to merge, we said this was a bold step forward for our industry. The name Eteris demonstrates our commitment to a new and exciting future for our company to create and enable technology innovations that improve the way people live.”

“Eteris is innovative and forward-looking and our logo symbolizes expanding future opportunities driving a new era of innovation and growth,” said Gary Dickerson, president and CEO of Applied Materials. “With a new name, mission and vision, we are bringing our new company into focus so that we can move quickly, execute our combined strategy and begin to create value as soon as the merger closes.”

Eteris captures the company’s focus on innovations that will enable its customers and move the industry forward. Core to Eteris is the promise to leave a positive and lasting impact on the world. Paired with the name is a bold logo that celebrates Eteris’ role in realizing the incredible possibility of technology. At the heart of the mark, the bright green square symbolizes the energy of the new company, the power of its technology and the foundation of innovation it provides to enable customer success. From the green foundation, bright colors and new dimensions expand, representing the many innovations Eteris will make possible every day. The logo represents expanding future opportunities that drive new innovation and growth.

joint_photo_eteris

The unveiling of the new company’s name and logo are the latest milestones in the merger’s progress. Last month the stockholders of Applied Materials and Tokyo Electron declared strong support for the combination. Approximately 99% of the shares voting at the Applied Materials stockholder meeting and 95% of the shares voting at the Tokyo Electron stockholder meeting voted to adopt the proposed business combination. These results underscore the value the combination brings to stockholders.

The closing of the business combination remains subject to customary conditions set forth in the parties’ Business Combination Agreement, including review by regulators in various countries. Applied Materials and Tokyo Electron expect the transaction to close in the second half of 2014.

Berger Pierre-DamienBy Pierre-Damien Berger, VP Business Development & Communication; CEA-Leti

Whatever forecast one uses for the future of the Internet of Things in terms of connected objects or business opportunities, the IoT will be big. Citing industry sources during of “The Internet of Things: from sensors to zero power,” the recent LetiDays conference in Grenoble, France, speakers offered projections venturing up to 50 billion connected objects by 2020.

Jacques Husser, COO of SIGFOX, said the IoT is the next major technological revolution, and that connecting billions or trillions of devices and enabling them to communicate with each other and will require more than high bandwidth. While increasing bandwidth is a key focus for multi-media and voice data network operators, for IoT companies reducing energy consumption and costs are key to handling the continuous volume of small messages from all those things.

SIGFOX, whose network is dedicated to the IoT, provides power-efficient, two-way wireless connectivity for IoT and machine-to-machine communications. Husser said the company’s technology is compatible with existing chipsets from vendors such as Texas Instruments, STMicroelectronics, Silicon Labs, Atmel, NXP and Semtech. Husser said that while SIGFOX’s technology complements 2G, 3G and 4G systems, it does not require a SIM card. Devices’ IP addresses are established during manufacturing.

The company, which has networks operating or in rollout with partners in several countries and major cities, is enabling applications for building and vehicle security, indoor climate monitoring, pet tracking, smart-city apps for parking and lighting management, asset management including billboard monitoring, water utility metering, and health-care apps like fall detection, distress signaling and medicine dispensing. Many more are expected.

Leti’s RF design and antenna expertise were used to help connect SIGFOX’s cellular networks. In addition, Leti is working with other startups and SMEs to develop and connect smart functions in a variety of products that will use the IoT to communicate. Primo1D was spun out of Leti in 2013 to produce E-Thread®, an innovative microelectronic packaging technology that embeds LEDs, RFIDs or sensors in fabric and materials for integration in textiles and plastics using standard production tools.

Leti startup BeSpoon recently launched SpoonPhone, a smartphone equipped with the capability to locate tagged items within a few centimeters’ accuracy. The capability is enabled by an impulse radio ultra-wideband (IR-UWB) integrated circuit developed by Leti and BeSpoon. Leti and Cityzen Sciences, the award-winning designer and developer of smart-sensing products, have begun a project to take the company’s technology to the next level by integrating micro-sensors in textiles during the weaving stage.

Leti and CORIMA, a leading supplier of carbon-composite wheels and frames for track and road-racing cyclists, are developing an integrated sensor system to measure the power output of riders as they pedal.

Citing research by Morgan Stanley Research, Leti’s telecommunications department head Dominique Noguet noted that worldwide shipments of smartphones and tablets exceeded shipments of desktop and notebook PCs for the first time in 2011. This signaled that the web has gone mobile, a fact underscored by a Cisco forecast that M2M mobile data traffic will increase 24x from 24 petabytes per month in 2012 to 563 petabytes in 2017.

Noguet said the IoT growth will present scaling challenges and require new communication protocols for sporadic, asynchronous, decentralized, low-power traffic. In addition to harvesting, or scavenging, energy to assure continuous connectivity, there will be demand for technologies that enable spectrum scavenging in unlicensed spectra, for example, and that use new bands, such as millimeter wave, white spaces and even light.

Leti has numerous ways to support development of the IoT, ranging from embedding antennas in specific materials through characterization and design, to implementing full-blown custom radio technologies. The inclusion of UHF RFID tags for the tire industry was cited as a first example where read/write range performances were a challenge. Leti’s ultra-wideband localization technology is another example where competence in signal processing, real-time design, antenna technology and mixed RF/digital ASIC design was combined to provide a complete solution where no off-the-shelf approach was available.

Noguet also noted potential threats to IoT security, and cited Leti’s involvement in the Santander, Spain, smart city project, which includes experimental advanced research on IoT technologies. Leti and CEA-List were in charge of securing access to the SmartSantander infrastructure and communications over a wireless sensor network. This included ensuring the security of the transactions and protecting users’ privacy.

By Shannon Davis, Web Editor

Many questions were in the air today at the 10th annual ConFab 2014, and perhaps one of the most interesting was raised during Dr. Roawen Chen of Qualcomm’s opening keynote, “What’s On Our Mind” when he asked, “Do we need Moore’s Law? Should we pursue it unconditionally?

The ConFab, held in Las Vegas, NV at The Encore, this week brings together over a hundred different top executives and key decision makers in the semiconductor and equipment supplier industries. Throughout the week, The ConFab allows a space for discussion in conference sessions as well as private meetings, allowing for much-needed industry collaboration.

We’ve often postulated extending Moore’s Law. We’ve even heard that it’s already dead.

Dr. Chen began his keynote with absolute certainty:

Pictured: Dr. Roawen Chen, Senior Vice President of Global Operation at Qualcomm

Pictured: Dr. Roawen Chen, Senior Vice President of Global Operation at Qualcomm

“The ride with Moore’s Law will eventually end,” he said, “but not because of a technical reason, but because of a financial reason.”

“I don’t think there will be enough volume for 7nm and below to make it a good ROI,” he continued.

He did, however, say that if EUV was ready tomorrow, it would change his outlook.

Dr. Chen remained quite positive that the semiconductor industry would flourish in spite of this and gave several reasons why this would be the case, chief among them was the growth of mobile applications and the resulting impact on the semiconductor industry.

Not everything demands Moore’s Law,” he said. “A lot of future, killer apps don’t need leading edge. You don’t need to migrate everything to leading edge.”

Given the current and growing complexity of consumer devices, in particular mobile, the need for new innovation and packaging solutions is bigger than ever, Dr. Chen explained.

“Innovation always wins,” he said. “We’ve been using the same playbook for many, many years. We have to adapt to the new reality.”

Ten years ago, he said, the enterprise was predictable and stable. PCs were the biggest semiconductor consumer – volume was higher, but seasonal. Smartphones, however, have become a lifestyle statement product, not just an IT device, and the demand has become more volatile.

Another change the semiconductor industry must adapt to is a new set of key industry drivers. The PC industry was driven by computing hardware, whereas the mobile ecosystem is driven by smartphone consumer data, not processing power, he explained. Surviving in a post-Moore’s Law world requires deriving value from downstream in the semiconductor ecosystem. Deeper collaboration within the supply chain is more necessary than ever before, Dr. Chen explained.

“The bull whip effect is also more pronounced in the mobile era,” said Dr. Chen, “and volatile customer demand amplifies the effect further up the supply chain.”

He also recommended a roadmap exchange on technology and manufacturing readiness.

Ultimately, while he has heard many in the industry sound apocalyptic-esque warnings, he and his Qualcomm colleagues remain optimistic.

“’The end is near’? I don’t believe so,” he said. “There is still plenty of opportunity for new innovation.”

Attendees of The ConFab 2014 at the morning keynote, sponsored by Brewer Science, on Monday, June 23, 2014.

Attendees of The ConFab 2014 at the morning keynote, sponsored by Brewer Science, on Monday, June 23, 2014.

Entropic announced plans today to close and consolidate several global facilities, a move that would impact approximately 23 percent of Entropic’s headcount. In its official release, Entropic said these plans are intended to align its cost structure around providing more focused engineering, R&D and product development programs.

Today’s actions, which are expected to be substantially completed by the fourth quarter of 2014, will place a higher concentration of engineering, R&D and product development efforts in San Diego, Irvine and San Jose, California, with specialized and local efforts maintained in Shanghai and Shenzhen, China and Belfast, Northern Ireland. Entropic will close major engineering sites in Austin, Texas; Israel; India; and Taiwan. By consolidating sites, Entropic anticipates it will be able to reduce product development complexity, create immediate operational efficiencies, and lower structural overhead costs.

Entropic offered approximately 30 percent of the staff in the facilities closing an opportunity to relocate to one of its California sites and expects to have approximately 500 employees at year’s end. Entropic is offering transition assistance to those impacted by the restructuring.

“Our actions today, while difficult to make as they affect our team of dedicated, talented employees, will enable Entropic to better target resources, improve short-term performance and accelerate our path to profitability while maintaining the proper level of investment in product development, the commercialization of new products, and general customer and design-win support,” said Patrick Henry, president and chief executive officer, Entropic.

Beginning in the fourth quarter of 2014, Entropic expects to realize approximately $6 million in quarterly savings, primarily in operating expenses mainly related to personnel and facilities expenses, with annualized savings in those same areas projected at $24 million.

The Company expects to incur a total pre-tax restructuring charge of approximately $5 million, of which roughly 75 percent is expected to be cash expenditures.

Today, Entropic also announced it lowered its previously announced financial guidance for the second quarter of 2014. Entropic now expects revenue for the second quarter to be in the range of $50 million to $51 million.

After two years of decline, fab equipment spending for Front End facilities in 2014 is expected to increase 24 percent in 2014 (US$35.7 billion) and about 11 percent (US$39.5 billion).  In terms of equipment spending, 2015 may reach or even surpass historic record year 2011 (about US$39.8 billion). For the May 2014 SEMI World Fab Forecast publication, SEMI tracked more than 200 major projects involving equipment spending for new equipment or upgrades, as well as projects to build new facilities or refurbish existing facilities.   In the last three months, 265 updates were made to the database. See Figure 1.

Figure 1

Figure 1

In 2014, the three largest regions for fab equipment spending will be Taiwan with over US$10.3 billion, the Americas with over US$6.8 billion, and Korea with over US$6.3 billion.  In 2015, these same regions will lead in spending: Taiwan will spend over US$11 billion, Korea over US$8 billion, and the Americas almost US$7 billion. Although in sixth in regional equipment spending this year, the Europe/Mideast region will show the strongest rate of growth, about 79 percent compared to the previous year.  The same region will continue to grow fast in 2015, with an increase of about 20 percent.

Worldwide installed capacity is very low for both 2014 and 2015 and the SEMI data does not suggest that this will change over the next four years. Because of the increased complexity of leading-edge nodes, such as more process steps and multiple patterning, fabs experience a decline in capacity as the same fab space produces less.  Worldwide, installed capacity grew by less than 2 percent in 2013 and is expected to grow just 2.5 percent in 2014 and 3 percent in 2015.

SEMI’s detailed data predict that Foundry capacity continues to grow at 8-10 percent yearly (a steady pace since 2012) and Flash is up 3 to 4 percent for 2014. Although DRAM equipment spending is expected to grow by 40 percent in 2014 as many fabs upgrade to a leading-edge process, installed capacity for DRAM is expected to stay flat or even drop 2 percent.  SEMI’s reports also cover capacity changes for other product segments:  MPU, Logic, Analog/Mixed signal, Power, Discretes, MEMS, and LED and Opto.

The SEMI World Fab Forecast uses a bottom-up approach methodology, providing high-level summaries and graphs, and in-depth analyses of capital expenditures, capacities, technology and products by fab. Additionally, the database provides forecasts for the next 18 months by quarter. These tools are invaluable for understanding how the semiconductor manufacturing will look in 2014 and 2015, and learning more about capex for construction projects, fab equipping, technology levels, and products.

The SEMI Worldwide Semiconductor Equipment Market Subscription (WWSEMS) data tracks only new equipment for fabs and test and assembly and packaging houses.  The SEMI World Fab Forecast and its related Fab Database reports track any equipment needed to ramp fabs, upgrade technology nodes, and expand or change wafer size, including new equipment, used equipment, or in-house equipment.

The 17th annual IITC will be held May 21 – 23, 2014 in conjunction with the 31st AMC at the Doubletree Hotel in San Jose, California, representing an annual series of meetings devoted to leading-edge research in the field of advanced metallization and 3D integration for ULSI IC applications. It will be preceded by a day-long workshop on “Manufacturing of Interconnect Technologies: Where are we now and where do we go from here?” today, Tuesday, May 20.

The 2014 IITC/AMC will focus on innovative developments in the critically important field of interconnections for electronic systems, presenting papers on all aspects of interconnects for device, circuit board and system-level applications. Topics include both fundamental and applied research, as well as issues related to introduction of enabling technologies into manufacturing. This year’s conference intends to provide a forum for open discussions ranging from basic science to industrial application, targeting material scientists, process and integration engineers and PhD students active in the areas of semiconductor processing, advanced materials, equipment development, and interconnect systems.

CLICK HERE TO LAUNCH SLIDESHOW

Further details are available at the conference website: http://www.ieee.org/conference/iitc

The Semiconductor Industry Association (SIA) today announced that worldwide sales of semiconductors reached $78.47 billion during the first quarter of 2014, marking the industry’s highest-ever first quarter sales. Global sales reached $26.16 billion for the month of March 2014, an increase of 11.4 percent from March 2013 when sales were $23.48 billion and a slight uptick of 0.4 percent compared to last month’s total of $26.04 billion. Regionally, sales in the Americas increased by 16.1 percent compared to last March, and year-to-year sales increased across all regions. All monthly sales numbers are compiled by the World Semiconductor Trade Statistics (WSTS) organization and represent a three-month moving average.

“The global semiconductor market has demonstrated consistent momentum in recent months, and sales are well ahead of last year’s pace through the first quarter of 2014,” said Brian Toohey, president and CEO, Semiconductor Industry Association. “Perhaps most impressively, sales in March increased across all regions and every semiconductor product category compared to last year, demonstrating the market’s broad and diverse strength.”

Regionally, year-to-year sales increased in the Americas (16.1 percent), Asia Pacific (12.9 percent), Europe (8 percent), and Japan (0.4 percent), marking the first time in more than three years that year-to-year sales increased across all regions. Sales were up compared to the previous month in Europe (3.9 percent), Asia Pacific (1.4 percent), and Japan (0.3 percent), but down slightly in the Americas (-4.3 percent).

“Although recent semiconductor sales are encouraging, one threat to the semiconductor market’s continued growth and America’s overall economic strength is the innovation deficit – the gap between needed and actual federal investments in research and higher education,” Toohey continued. “Policymakers should act swiftly to close the innovation deficit by committing to robust and sustained investments in basic scientific research and higher education.”

March 2014
Billions
Month-to-Month Sales
Market Last Month Current Month % Change
Americas 5.32 5.09 -4.3%
Europe 2.96 3.07 3.9%
Japan 2.81 2.81 0.3%
Asia Pacific 14.96 15.18 1.4%
Total 26.04 26.16 0.4%
Year-to-Year Sales
Market Last Year Current Month % Change
Americas 4.39 5.09 16.1%
Europe 2.85 3.07 8.0%
Japan 2.80 2.81 0.4%
Asia Pacific 13.45 15.18 12.9%
Total 23.48 26.16 11.4%
Three-Month-Moving Average Sales
Market Oct/Nov/Dec Jan/Feb/Mar % Change
Americas 5.80 5.09 -12.2%
Europe 2.96 3.07 3.9%
Japan 2.93 2.81 -3.8%
Asia Pacific 14.96 15.18 1.4%
Total 26.65 26.16 -1.8%

 

Samsung Electronics said today that it has begun mass producing the industry’s first high-performance, three-bit-NAND-based SSD for servers and data centers. The new SSD will allow data centers to better manage workloads related to social networking, web browsing and email, and enhance operation efficiency. Installations of the 3-bit MLC (multi-level-cell) NAND SSDs, initially in large-scale data centers, are expected to begin later this quarter.

“Following the last year’s introduction of 3-bit NAND-based SSDs for PC markets, our new 3-bit SSD for data centers will help considerably in expanding the market base for SSDs,” said Young-Hyun Jun, executive vice president, memory sales and marketing, Samsung Electronics. “We expect SSD market growth will gain momentum as this new SSD delivers significant improvements in data center investment efficiency, leading to full-fledged commercialization of SSDs in IT systems later this year.”

The new PM853T SSD, available in densities of 240GB, 480GB and 960GB, offers high levels of random IOPS (inputs/output per second) performance and quality of service (QoS), both essential for data center and cloud server applications. In light of these benefits, Samsung expects the adoption of 3-bit SSDs in data centers to advance rapidly in replacing the 2-bit SSD market.

In broadening the market base for SSDs, the new PM853T SSD will enable IT managers to optimize their SSD upgrades at investment levels similar to those of consumer SSDs. The PM853T delivers a 30 percent increase in manufacturing efficiency compared to SSDs that use 2-bit NAND flash components.

Utilizing Samsung’s 10nm-class 3-bit NAND flash components and advanced controller technology, the new drive features a sequential read speed of 530 megabytes per second (MB/s), while writing sequentially at 420MB/s. It also will read data randomly at 90,000 IOPS and handle sustained random writes at 14,000 IOPS.

Since it first produced the 3-bit NAND-based 840 EVO SSD in 2012, Samsung has taken the lead in providing SSDs for ultra-slim notebooks and PCs. With the PM853T, it has now secured a strong foothold for high-efficiency SSDs in large data centers.

Through this introduction of a SATA 6Gb/s 3-bit SSD, Samsung is reinforcing its collaboration with global data center and server customers, while continuing to offer the broadest line up of competitive SSDs (spanning SATA, SAS, and PCIe/NVMe interfaces) to increase its leadership position in the premium SSD market.

According to a market research report from IHS iSuppli, the global SSD market is expected to grow approximately 30 percent from U.S. $9.4 billion in 2013 to U.S. $12.4 billion in 2014. The report says it will also maintain a high growth rate over the next several years, reaching up to U.S. $20 billion in 2017.

Dow Corning filed a complaint through its Chinese subsidiary and licensee with the Shanghai First Intermediate Court. The complaint alleges that Beijing KMT Technology Co., Ltd infringed Dow Corning’s Chinese patent by manufacturing and selling products using proprietary Dow Corning silicone technology under the Beijing KMT label.

The patent is part of Dow Corning’s diverse and multilayered intellectual property (IP) portfolio protecting its high refractive index (RI) phenyl-based optical silicone encapsulants, which offer numerous high-value benefits to LED devices. These benefits include improved light output, excellent mechanical protection of LED components and enduring gas barrier properties for enhanced reliability.

“Dow Corning will always rigorously defend its intellectual property to ensure that our customers continue to receive the highest quality products and reliability we can provide to help them stay competitive in today’s fast-growing LED market,” said Kaz Maruyama, global industry director, Lighting Solutions, Dow Corning.

For nearly 15 years, Dow Corning has invested aggressively to develop optical silicone technologies and products designed to advance applications along the entire LED value chain – in China and across the globe. Among these materials are Dow Corning’s phenyl-based high RI silicone encapsulants, which the company began innovating over a decade ago in Japan where the technology was first patented. Additional patents for these advanced optical materials quickly followed in Korea, the United States, European Union, Taiwan, Malaysia and other countries. Chinese Patent asserted in the complaint against Beijing KMT, was granted on April 2, 2008.

“Asia currently leads the market transition to LEDs for general lighting, driven especially by swift penetration in China,” said Maruyama. “Supply chain integrity and consistent material quality are both key factors in ensuring that LEDs offer a credible, cost-effective alternative to conventional lighting. It takes only a few failed applications to raise doubts about the technology’s viability for future investment and adoption. Consequently, industry-wide defense and support of proven, patented and cutting-edge LED solutions such as Dow Corning’s OE Series helps validate the competitive value of LED lighting, and advances the interests of all.”