Category Archives: Semiconductors

WIN Semiconductors Corp (TPEx:3105), the world’’s largest pure-play compound semiconductor foundry, has expanded its gallium nitride (GaN) process capabilities to include a 0.45?m-gate technology that supports current and future 5G applications. The NP45-11 GaN-on-SiC process allows customers to design hybrid Doherty power amplifiers used in 5G applications including massive MIMO (multiple-input and multiple-output) wireless antenna systems. Similar to macro-cell applications, MIMO base stations often combine Doherty power amplifiers with linearization techniques to meet demanding linearity and efficiency specifications of today’s wireless infrastructure.

GaN devices outperform the incumbent LDMOS technology, offering superior efficiency, instantaneous bandwidth and linearity, particularly in the higher frequency bands utilized in 5G radio access networks.

Ideal for use in sub-6 GHz 5G applications including macro-cell transmitters and MIMO access points, the NP45-11 technology supports power applications from 100 MHz through 6GHz. This discrete transistor process is environmentally rugged, incorporating advanced moisture protection and meets the JEDEC JESD22-A110 biased HAST qualification at 55 volts. Combined with WIN Semiconductors’ environmentally rugged high voltage passive technology, IP3M-01, the NP45-11 technology enables hybrid power amplifiers in a low cost plastic package.

The NP45-11 technology is fabricated on 100mm silicon carbide substrates and operates at a drain bias of 50 volts. In the 2.7GHz band, this technology provides saturated output power of 7 watts/mm with 18 dB linear gain and more than 65% power added efficiency without harmonic tuning.

“5G radio access networks create several challenges to power amplifier designs used in MIMO systems. High output power and linear efficiency are primary design objectives to meet performance specifications and lower total cost of ownership. The tradeoff between output power and linearized efficiency is significant because of the high peak-to-average power ratio employed in today’s wireless modulation schemes. This tradeoff becomes more difficult in 5G applications due to greater instantaneous bandwidth requirements and higher operating frequency,” said David Danzilio, Senior Vice President of WIN Semiconductors Corp.

With the rapid rise of AI providing overwhelming possibilities for industry growth, SEMICON West has been designed to help the microelectronics industry get a firm handle on how best to enable and take advantage of AI’s potential. From the lab to the fab, and from design through system, the benefits from conversations at the event will be felt across transportation, medical, manufacturing, IoT and Big Data.

With the world’s interest racing toward how Artificial Intelligence (AI) can accelerate so many things, six visionary keynoters will reveal what lies ahead for semiconductors and society. Forecasting tomorrow’s trends and their impacts, the keynoters plan to illustrate the semiconductor’s path to enabling a global state of “Beyond Smart.” Complementing the keynotes, nearly 120 experts from multiple disciplines will analyze pivotal aspects of trends that are driving the emerging markets for microelectronics. This year’s preeminent event, SEMICON West, will be held at the Moscone Center in San Francisco, July 10-12.

“SEMICON West is the timeless home where the world’s next innovations are previewed and accelerated,” said David Anderson, President of SEMI Americas. “With the dawn of the AI era ramping up globally, we’ve assembled the richest lineup of talent and resources in SEMI history.”

BEYOND SMART

Through both artificial and organic cognition, the ways that intelligence is being cultivated will be profiled and mapped by world-renowned keynoters:

  • Dr. John E. Kelly, III, Senior Vice President, IBM Cognitive Solutions and IBM Research
  • Gary Dickerson, Chief Executive Officer, Applied Materials
  • Amir Husain, Chief Executive Officer, SparkCognition, and author of The Sentient Machine: the Coming Age of Artificial Intelligence
  • Dr. Melissa Schilling, Professor, New York University Stern School of Business and author of Quirky: The Remarkable Genius of Breakthrough Innovators Who Changed the World
  • Mark Papermaster, Chief Technology Officer, Advanced Micro Devices
  • Dr. Wolfgang Juchmann, Vice President, AutonomouStuff

Dr. Kelly of IBM has shared in interviews that he was an “early-on” believer in Moore’s Law, where he built much of his career. Now, he sees the industry embarking on the early part of an “AI’s Law.” He is focused on IBM’s investments in several new and future areas of the fastest-growing and most strategic parts of the information technology market. He also oversees the specialization of IBM Watson into various industries and domains.

Gary Dickerson of Applied Materials is as well-versed as anyone about the history, and future, of the chip business. In addition to Applied, he also has led semiconductor equipment companies Varian Equipment and KLA-Tencor in their top executive positions for 25 years. His insights to be presented at SEMICON West will include first-hand knowledge of how the markets are changing and where will be the opportunities for the toolmaking and chipmaking businesses.

Amir Husain of SparkCognition argues — from his background as an inventor and computer scientist — that with AI, the chip industry is on the cusp of writing its next, and greatest, creations. Also author of The Sentient Machine, he’ll examine for the audience what complex computer science and AI concepts will mean for a wide variety of chip technologies, including the resulting cultural benefits and challenges. Husain is an advocate for embracing AI in order to advance the state of the art in many critical fields, including security, resource management, finance and energy.

Dr. Melissa Schilling of NYU’s Stern School of Business will speak about “creative genius” as partial reflection of her research focus on innovation and strategy in high-tech industries such as smartphones, gaming, pharmaceuticals, biotechnology, electric vehicles and renewable energies. She’s well-studied in platform dynamics, networks, creativity and breakthrough innovation. As author of several innovation strategy textbooks and the recently released book Quirky, she suggests that regardless of whether an innovator is a one-hit wonder or a serial disruptor, a common thread among those introverts and extroverts alike is their cultivation of talents for the benefit of society.

Mark Papermaster of AMD is a veteran of silicon engineering at Apple, Cisco and IBM. He’s responsible for corporate technical direction, product development including system-on-chip (SOC) methodology, microprocessor design, I/O and memory, and advanced research. He also oversees Information Technology to deliver AMD’s compute infrastructure and services. From his leadership roles managing the development of products — from microprocessors to mobile devices and high-performance servers — Papermaster will offer his insights and forecasts around the inflection points for semiconductor applications and AI.

Dr. Wolfgang Juchmann of AutonomouStuff is expert in future automotive options and with the technologies that enable perception sensors, LiDAR and autonomous vehicles. He will include discussion of how and where advanced autonomous driving tasks will rely on new capabilities for radar, vision and ultra-sonic sensors, real-time 3D data fusion middleware, fully by-wire controllable autonomous development vehicles and modular software algorithms.

The Semiconductor Industry Association (SIA), representing U.S. leadership in semiconductor manufacturing, design, and research, today announced worldwide sales of semiconductors reached $37.6 billion for the month of April 2018, an increase of 20.2 percent from the April 2017 total of $31.3 billion and 1.4 percent more than last month’s total of $37.1 billion. Monthly sales numbers are compiled by the World Semiconductor Trade Statistics (WSTS) organization and represent a three-month moving average. Additionally, a newly released WSTS industry forecast projects annual global market growth of 12.4 percent in 2018 and 4.4 percent in 2019.

“The global semiconductor industry has posted consistently strong sales so far in 2018, and the global market has now experienced year-to-year growth of greater than 20 percent for 13 consecutive months,” said John Neuffer, president and CEO, Semiconductor Industry Association. “Although boosted in part by impressive growth in the memory market, sales of non-memory products also grew by double digits in April on a year-to-year basis, and all major regional markets posted double-digit year-to-year gains. The global market is projected to experience significant annual growth this year, with more modest growth expected next year.”

Regionally, year-to-year sales increased in the Americas (34.1 percent), China (22.1 percent), Europe(21.4 percent), Japan (14.6 percent), and Asia Pacific/All Other (10.2 percent). Compared with last month, sales were up in China (3.2 percent), Japan (2.7 percent), Europe (1.4 percent), and the Americas (0.8 percent), but down slightly in Asia Pacific/All Other (-0.8 percent).

Additionally, SIA today endorsed the WSTS Spring 2018 global semiconductor sales forecast, which projects the industry’s worldwide sales will be $463.4 billion in 2018. This would mark the industry’s highest-ever annual sales, a 12.4 percent increase from the 2017 sales total. WSTS projects year-to-year increases across all regional markets for 2018: the Americas (14.0 percent), Europe (13.4 percent), Asia Pacific (including China) (12.3 percent), and Japan (8.6 percent). In 2019, growth in the semiconductor market is expected to moderate, with sales increases of between 4-5 percent expected across each of the regions. WSTS tabulates its semi-annual industry forecast by convening an extensive group of global semiconductor companies that provide accurate and timely indicators of semiconductor trends.

For comprehensive monthly semiconductor sales data and detailed WSTS Forecasts, consider purchasing the WSTS Subscription Package. For information about the global semiconductor industry and market, check out SIA’s free 2018 Factbook.

Apr 2018

Billions

Month-to-Month Sales                              

Market

Last Month

Current Month

% Change

Americas

8.10

8.16

0.8%

Europe

3.58

3.63

1.4%

Japan

3.21

3.30

2.7%

China

11.98

12.36

3.2%

Asia Pacific/All Other

10.23

10.15

-0.8%

Total

37.09

37.59

1.4%

Year-to-Year Sales

Market

Last Year

Current Month

% Change

Americas

6.08

8.16

34.1%

Europe

2.99

3.63

21.4%

Japan

2.88

3.30

14.6%

China

10.12

12.36

22.1%

Asia Pacific/All Other

9.21

10.15

10.2%

Total

31.28

37.59

20.2%

Three-Month-Moving Average Sales

Market

Nov/Dec/Jan

Feb/Mar/Apr

% Change

Americas

8.63

8.16

-5.5%

Europe

3.40

3.63

6.6%

Japan

3.21

3.30

2.8%

China

12.01

12.36

2.9%

Asia Pacific/All Other

10.35

10.15

-1.9%

Total

37.60

37.59

0.0%

Worldwide industrial semiconductor revenues grew by 11.8 percent year over year, reaching $49.1 billion in 2017, according to the latest analysis from IHS Markit (Nasdaq: INFO). Industrial electronics equipment demand was broad-based, with continued growth in commercial and military aircraft, LED lighting, digital signage, digital video surveillance, climate control, smart meters, traction, photovoltaic (PV) inverters, human machine interface and various medical electronics like cardiac equipment, hearing aids, endoscopy and imaging systems. The industry is expected to grow at a compound annual growth rate (CAGR) of 7.1 percent through 2022.

Optical semiconductors delivered excellent performance, due to the continued strength of the general LED lighting market. Power discretes demand has ramped up in industrial motor drives, EV chargers, PV inverters, traction and lighting equipment. General purpose analog has a strong five-year growth in various industrial markets, especially in factory automation, power and energy, and lighting. Microcontrollers (MCUs) are also projected to experience broad-based growth in the long term, thanks to advances in power efficiency and integration features.

“The resilient economy in the United States, and strong demand in China, carried the lion’s share of industrial equipment demand in 2017,” said Robbie Galoso, associate director and principal analyst, industrial semiconductors, for IHS Markit. “A European resurgence also provided a strong tailwind for semiconductor growth.”

Global industrial semiconductor market share rankings

Strategic acquisitions continued to play a major role in shaping the overall semiconductor market rankings in key industrial semiconductor segments. All the following top 10 industrial semiconductor suppliers achieved revenue growth in 2017:

  1. Texas Instruments (TI) maintained its position as the largest industrial semiconductor supplier in 2017.
  2. The acquisition of Linear Technology catapulted Analog Devices into second position.  The combined Analog Devices and Linear Technology company generated $2.8 billion in industrial revenue in 2017. This acquisition boosted ADI’s industrial market shares in diversified segments within factory automation, military aerospace, video surveillance, test and measurement, medical, and power and energy applications.
  3. Intel ranked third, as the company’s Internet of Things (IoT) division continued to generate double-digit revenue growth attributed to innovation and strength in its factory automation, video surveillance and medical segments. Growth was also aided by the proliferation of smart and connected devices and a tremendous uplift in data analytics.
  4. Ranking fourth, Infineon’s strong revenue growth continued to be led by industrial applications, especially in factory automation, traction and various power and energy segments like PV, electric vehicle chargers and power supplies, where its leading discrete and power management devices are used.
  5. In fifth position, STMicroelectronics solid industrial revenue stream stems from a variety of applications, including factory and building automation, where its MCU, analog and discrete components are used.
  6. Micron’s organic revenue from industrial businesses continued to flourish in 2017, pushing the company into sixth place, driven by dynamic random-access memory (DRAM) growth in industrial IoT (IIoT) markets, spanning factory automation, video surveillance and transportation.
  7. Toshiba ranked seventh, with industrial electronics revenue growing to $1.5 billion in 2017. Growth was driven by power transistor discretes, MCU, optical and logic integrated circuit (IC) solutions in manufacturing and process automation, power and energy, and building and home control.
  8. Microchip Technology ranked eighth, and its revenue growth was primarily supported by MCU solutions in manufacturing and process automation, power and energy, and building and home control.
  9. ON Semiconductor was ranked ninth in 2017, driven by manufacturing and process automation, including machine vision, power and energy, building automation and hearing aids and other medical devices.
  10. NXP ranked tenth in the industrial market, with its strong presence in manufacturing and process automation, building and home control, medical electronics and other industrial applications.

Although not part of the top 10 ranking, China’s massive investments in LED manufacturing were especially noteworthy. Chinese firm MLS rose from 18th to 13th place, after posting 50 percent revenue growth and reaching $1 billion in 2017. MLS beat out other leading general lighting LEDs suppliers Nichia, Osram and Cree.

Ever shrinking transistors are the key to faster and more efficient computer processing. Since the 1970s, advancements in electronics have largely been driven by the steady pace with which these tiny components have grown simultaneously smaller and more powerful–right down to their current dimensions on the nanometer scale. But recent years have seen this progress plateau, as researchers grapple with whether transistors may have finally hit their size limit. High among the list of hurdles standing in the way of further miniaturization: problems caused by “leakage current.”

Leakage current results when the gap between two metal electrodes narrows to the point that electrons are no longer contained by their barriers, a phenomenon known as quantum mechanical tunnelling. As the gap continues to decrease, this tunnelling conduction increases at an exponentially higher rate, rendering further miniaturization extremely challenging. Scientific consensus has long held that vacuum barriers represent the most effective means to curtail tunnelling, making them the best overall option for insulating transistors. However, even vacuum barriers can allow for some leakage due to quantum tunnelling.

In a highly interdisciplinary collaboration, researchers across Columbia Engineering, Columbia University Department of Chemistry, Shanghai Normal University, and the University of Copenhagen have upended conventional wisdom, synthesizing the first molecule capable of insulating at the nanometer scale more effectively than a vacuum barrier. Their findings are published online today in Nature.

“We’ve reached the point where it’s critical for researchers to develop creative solutions for redesigning insulators. Our molecular strategy represents a new design principle for classic devices, with the potential to support continued miniaturization in the near term,” said Columbia Engineering physicist and co-author Latha Venkataraman, who heads the lab where researcher Haixing Li conducted the project’s experimental work. Molecular synthesis was carried out in the Colin Nuckolls Lab at Columbia’s Department of Chemistry, in partnership with Shengxiong Xiao at Shanghai Normal University.

The team’s insight was to exploit the wave nature of electrons. By designing an extremely rigid silicon-based molecule under 1 nm in length that exhibited comprehensive destructive interference signatures, they devised a novel technique for blocking tunnelling conduction at the nanoscale.

“This quantum interference-based approach sets a new standard for short insulating molecules,” said lead author Marc Garner, a chemist in the University of Copenhagen’s Solomon Lab, which handled the theoretical work. “Theoretically, interference can lead to complete cancellation of tunneling probability, and we’ve shown that the insulating component in our molecule is less conducting than a vacuum gap of same dimensions. At the same time, our work also improves on recent research into carbon-based systems, which were thought to be the best molecular insulators until now.”

Destructive quantum interference occurs when the peaks and valleys of two waves are placed exactly out of phase, annulling oscillation. Electronic waves can be thought of as analogous to sound waves–flowing through barriers just as sound waves “leak” through walls. The unique properties exhibited by the team’s synthetic molecule mitigated tunneling without requiring, in this analogy, a thicker wall.

Their silicon-based strategy also presents a potentially more factory-ready solution. While recent research into carbon nanotubes holds promise for industrial applications over the next decade or so, this insulator–compatible with current industry standards–could be more readily implemented.

“Congratulations to the team on this breakthrough,” said Mark Ratner, a pioneer in the field of molecular electronics and professor emeritus at Northwestern University who was not involved in the study. “Using interference to create an insulator has been ignored up to this date. This paper demonstrates the ability of interference, in a silicon-based sigma system, which is quite impressive.”

This breakthrough grew out of the team’s larger project on silicon-based molecule electronics, begun in 2010. The group arrived at their latest discovery by bucking the trend. Most research in this field aims to create highly conducting molecules, as low conductance is rarely considered a desirable property in electronics. Yet insulating components may actually prove to be of greater value to future optimization of transistors, due to the inherent energy inefficiencies caused by leakage currents in smaller devices.

As a result, their work has yielded new understanding of the fundamental underlying mechanisms of conduction and insulation in molecular scale devices. The researchers will build on this insight by next clarifying the details of structure-function relationships in silicon-based molecular components.

“This work has been extremely gratifying for us, because in the course of it we have repeatedly discovered new phenomena,” said Venkataraman. “We have previously shown that silicon molecular wires can function as switches, and now we’ve demonstrated that by altering their structure, we can create insulators. There is a lot to be learned in this area that will help shape the future of nanoscale electronics.”

ROHM, a supplier of power semiconductors, and GaN Systems, a developer of GaN power semiconductors, today announced their collaboration in the GaN (gallium nitride) Power Semiconductor business, with the goal of contributing to the continuing evolution of power electronics.

This strategic partnership leverages GaN Systems’ industry leading capabilities in power GaN transistors along with ROHM’s comprehensive footprint in semiconductor and considerable resources in the design and manufacture of electronic components. The companies have agreed to jointly develop form-, fit-, and function-compatible products using GaN semiconductor dies in both GaN Systems’ GaNPX® packaging and ROHM’s traditional power semiconductor packaging. GaN Systems and ROHM customers will now have the advantage of having two possible sources for package-compatible GaN power switches, presenting the widest selection of dual-sourced GaN devices.

Customers will also benefit from greater access to GaN products and resources globally, especially in Asia, one of the fastest growing market for GaN. In addition, GaN Systems and ROHM will work together on GaN semiconductor research and development activities to propose ground-breaking solutions for the industrial, automotive, and consumer electronics fields. And to contribute to greater energy savings and increased power densities in the power electronics market, both companies will continue to collaborate to expand their line-up of GaN products and broaden the range of choices.

“GaN has rapidly made its ascent into power electronics applications and this partnership exemplifies how important GaN has become in a complete power electronics offering,” said Jim Witham, CEO of GaN Systems. “We’re proud to partner with ROHM, a company well-known for developing industry-leading technologies. By combining our joint expertise and capabilities, we’re enabling more businesses to access and experience the benefits of GaN in achieving higher power, more efficient, smaller, and lighter power electronics.”

“ROHM has targeted the power device business as one of our growth strategies. We offer leading-edge products such as SiC (Silicon Carbide) power devices and provide power solutions that integrate control technologies, including gate drivers that maximize device performance. We are also developing GaN for next-generation power devices. By leveraging the superior technologies and expertise of both companies, we are able to accelerate the development of high-performance solutions to solve the needs of the power market,” said Katsumi Azuma, Senior Managing Director of ROHM Semiconductor.

Applied Materials, Inc. today announced a breakthrough in materials engineering that accelerates chip performance in the big data and AI era.

In the past, classic Moore’s Law scaling of a small number of easy-to-integrate materials simultaneously improved chip performance, power and area/cost (PPAC). Today, materials such as tungsten and copper are no longer scalable beyond the 10nm foundry node because their electrical performance has reached physical limits for transistor contacts and local interconnects. This has created a major bottleneck in achieving the full performance potential of FinFET transistors. Cobalt removes this bottleneck but also requires a change in process system strategy. As the industry scales structures to extreme dimensions, the materials behave differently and must be systematically engineered at the atomic scale, often under vacuum.

To enable the use of cobalt as a new conducting material in the transistor contact and interconnect, Applied has combined several materials engineering steps – pre-clean, PVD, ALD and CVD – on the Endura® platform. Moreover, Applied has defined an integrated cobalt suite that includes anneal on the Producer® platform, planarization on the Reflexion® LK Prime CMP platform and e-beam inspection on the PROVision platform. Customers can use this proven, Integrated Materials Solution to speed time-to-market and increase chip performance at the 7nm foundry node and beyond.

“Five years ago, Applied anticipated an inflection in the transistor contact and interconnect, and we began developing an alternative materials solution that could take us beyond the 10nm node,” said Dr. Prabu Raja, senior vice president of Applied’s Semiconductor Products Group. “Applied brought together its experts in chemistry, physics, engineering and data science to explore the broad portfolio of Applied’s technologies and create a breakthrough Integrated Materials Solution for the industry. As we enter the big data and AI era, there will be more of these inflections, and we are excited to be having earlier and deeper collaborations with our customers to accelerate their roadmaps and enable devices we never dreamed possible.”

While challenging to integrate, cobalt brings significant benefits to chips and chip making: lower resistance and variability at small dimensions; improved gapfill at very fine dimensions; and improved reliability. Applied’s integrated cobalt suite is now shipping to foundry/logic customers worldwide.

Applied Materials, Inc. (Nasdaq:AMAT) is a leader in materials engineering solutions used to produce virtually every new chip and advanced display in the world.

A new way of enhancing the interactions between light and matter, developed by researchers at MIT and Israel’s Technion, could someday lead to more efficient solar cells that collect a wider range of light wavelengths, and new kinds of lasers and light-emitting diodes (LEDs) that could have fully tunable color emissions.

The fundamental principle behind the new approach is a way to get the momentum of light particles, called photons, to more closely match that of electrons, which is normally many orders of magnitude greater. Because of the huge disparity in momentum, these particles usually interact very weakly; bringing their momenta closer together enables much greater control over their interactions, which could enable new kinds of basic research on these processes as well as a host of new applications, the researchers say.

The new findings, based on a theoretical study, are being published today in the journal Nature Photonics in a paper by Yaniv Kurman of Technion (the Israel Institute of Technology, in Haifa); MIT graduate student Nicholas Rivera; MIT postdoc Thomas Christensen; John Joannopoulos, the Francis Wright Davis Professor of Physics at MIT; Marin Soljacic, professor of physics at MIT; Ido Kaminer, a professor of physics at Technion and former MIT postdoc; and Shai Tsesses and Meir Orenstein at Technion.

While silicon is a hugely important substance as the basis for most present-day electronics, it is not well-suited for applications that involve light, such as LEDs and solar cells — even though it is currently the principal material used for solar cells despite its low efficiency, Kaminer says. Improving the interactions of light with an important electronics material such as silicon could be an important milestone toward integrating photonics — devices based on manipulation of light waves — with electronic semiconductor chips.

Most people looking into this problem have focused on the silicon itself, Kaminer says, but “this approach is very different — we’re trying to change the light instead of changing the silicon.” Kurman adds that “people design the matter in light-matter interactions, but they don’t think about designing the light side.”

One way to do that is by slowing down, or shrinking, the light enough to drastically lower the momentum of its individual photons, to get them closer to that of the electrons. In their theoretical study, the researchers showed that light could be slowed by a factor of a thousand by passing it through a kind of multilayered thin-film material overlaid with a layer of graphene. The layered material, made of gallium arsenide and indium gallium arsenide layers, alters the behavior of photons passing through it in a highly controllable way. This enables the researchers to control the frequency of emissions from the material by as much as 20 to 30 percent, says Kurman, who is the paper’s lead author.

The interaction of a photon with a pair of oppositely charged particles — such as an electron and its corresponding “hole” — produces a quasiparticle called a plasmon, or a plasmon-polariton, which is a kind of oscillation that takes place in an exotic material such as the two-dimensional layered devices used in this research. Such materials “support elastic oscillations on its surface, really tightly confined” within the material, Rivera says. This process effectively shrinks the wavelengths of light by orders of magnitude, he says, bringing it down “almost to the atomic scale.”

Because of that shrinkage, the light can then be absorbed by the semiconductor, or emitted by it, he says. In the graphene-based material, these properties can actually be controlled directly by simply varying a voltage applied to the graphene layer. In that way, “we can totally control the properties of the light, not just measure it,” Kurman says.

Although the work is still at an early and theoretical stage, the researchers say that in principle this approach could lead to new kinds of solar cells capable of absorbing a wider range of light wavelengths, which would make the devices more efficient at converting sunlight to electricity. It could also lead to light-producing devices, such as lasers and LEDs, that could be tuned electronically to produce a wide range of colors. “This has a measure of tunability that’s beyond what is currently available,” Kaminer says.

“The work is very general,” Kurman says, so the results should apply to many more cases than the specific ones used in this study. “We could use several other semiconductor materials, and some other light-matter polaritons.” While this work was not done with silicon, it should be possible to apply the same principles to silicon-based devices, the team says. “By closing the momentum gap, we could introduce silicon into this world” of plasmon-based devices, Kurman says.

Because the findings are so new, Rivera says, it “should enable a lot of functionality we don’t even know about yet.”

Dow Performance Silicones further enhanced design flexibilities and processing options for consumer device and display OEMs today with the addition of DOWSIL™ SE 9100 and DOWSIL™ SE 9160 Adhesives to its portfolio of one-part, room-temperature cure (RTV) silicone solutions. In addition to offering versatile processing options, the two new silicone adhesives bond well to most substrates, deliver excellent rework ability with no residue, exhibit high flow to fill narrow gaps, and enable cure-in-place-gaskets (CIPG) that offer effective seals compatible with IPX7-rated water resistance.

DOWSIL™ SE 9100 Adhesive is a one-part silicone formulation that achieves fast tack-free processing at room temperature with the option to accelerate cure with the application of heat. It demonstrates low (< 1 percent) shrinkage by volume after cure to minimize internal stress for optimal sealing, and offers cost-effective processing and repairability during the assembly of mobile and display modules and other consumer devices.

DOWSIL™ SE 9160 Adhesive exhibits many of these same properties, yet its dual-cure formulation offers the option of faster in-line processing through irradiation with ultraviolet (UV) energy at densities as low as 4,000mJ/cm2 to component assembly to continue within seconds. Higher densities (10,000mJ/cm2) enable the material to quickly achieve full, deep section cure. In addition, in designs where the silicone adhesive is partially “in shadow” from the UV lamp, Dow’s new innovative silicone adhesive will still secure rapid moisture cure.

DOWSIL™ SE 9160 Adhesive is suitable for sealing small- to medium-sized consumer devices such as smart phones, tablets and displays. It is particularly effective at sealing air gaps or holes between LCD or OLED display panels and their plastic cover frames.

“Consumer device manufactures are under constant pressure to make their products more reliable, more profitable and packed with ever more features,” said Jayden Cho, global marketing segment leader, Consumer Devices at Dow Performance Silicones. “These two highly innovative silicone adhesives aim to help our global customers successfully address all three of these challenges as they push the boundaries of their next-generation device designs.”

Dow’s two new adhesives are available globally under the new DOWSIL™ label, which builds on seven decades of innovation and proven performance from the heritage Dow Corning silicone technology platform.

At this week’s 2018 IEEE International Interconnect Technology Conference (IITC 2018), imec will present 11 papers on advanced interconnects, ranging from extending Cu and Co damascene metallization, all the way to evaluating new alternatives such as Ru and graphene. After careful evaluation of the resistance and reliability behavior, imec takes first steps towards extending conventional metallization into to the 3nm technology node.

For almost two decades, Cu-based dual damascene has been the workhorse industrial process flow for building reliable interconnects. But when downscaling logic device technology towards the 5nm and 3nm technology nodes, meeting resistance and reliability requirements for the tightly pitched Cu lines has become increasingly challenging. The industry is however in favor of extending the current damascene technology as long as possible, and therefore, different solutions have emerged.

To set the limits of scaling, imec has benchmarked the resistance of Cu with respect to Co and Ru in a damascene vehicle with scaled dimensions, demonstrating that Cu still outperforms Co for wire cross sections down to 300nm2 (or linewidths of 12nm), which corresponds to the 3nm technology node. To meet reliability requirements, one option is to use Cu in combination with thin diffusion barriers such as tantalum nitride (TaN)) and liners such as Co or Ru. It was found that the TaN diffusion barrier can be scaled to below 2nm while maintaining excellent Cu diffusion barrier properties.

For Cu linewidths down to 15–12nm, imec also modeled the impact of the interconnect line-edge roughness on the system-level performance. Line-edge roughness is caused by the lithographic and patterning steps of interconnect wires, resulting in small variations in wire width and spacing. At small pitches, these can affect the Cu interconnect resistance and variability. Although there is a significant impact of line-edge roughness on the resistance distribution for short Cu wires, the effect largely averages out at the system level.

An alternative solution to extend the traditional damascene flow is replacing Cu by Co. Today Co requires a diffusion barrier – an option that recently gained industrial acceptance. A next possible step is to enable barrierless Co or at least sub-nm barrier thickness with careful interface engineering. Co has the clear advantage of having a lower resistance for smaller wire cross-secions and smaller vias. Based on electromigration and thermal storage experiments, imec presents a detailed study of the mechanisms that impact Co via reliability, showing the abscence of voids in barrierless Co vias, demonstrating a better scalability of Co towards smaller nodes.

The research is performed in cooperation with imec’s key nano interconnect program partners including GlobalFoundries, Huawei, Intel, Micron, Qualcomm, Samsung, SK Hynix, SanDisk/Western Digital, Sony Semiconductor Solutions, TOSHIBA Memory and TSMC.