Category Archives: Semiconductors

An estimated 405 million handsets, including 197 million smartphones, were shipped in the first quarter of 2013, according to market intelligence firm ABI Research. Smartphone shipments grew 38 percent year-over-year (YoY) while feature phone shipments declined 5.2% YoY. Shipments of all handsets grew 12 percent YoY in the first quarter thanks to the continued strength of the smartphone market, which achieved an all-time high of 49% shipment penetration.

“Worldwide handset and smartphone shipments exhibited classic Q1 softness,” says senior analyst Michael Morgan. “Samsung accomplished strong smartphone growth while Apple dismissed a troubling mix of slowed growth and declining margins as a sign that the older iPhone 4S was in high demand.”

Nokia handset shipments plummeted to 62 million in Q1 with smartphone shipments at a 5-year low of 6.1 million. Considering market and OEM specific conditions, BlackBerry delivered a respectable 6 million shipments, with 1 million coming from the launch of BlackBerry 10-based devices. Despite HTC’s well-designed ONE devices, shipments continued to decline 37 percent YoY to 4.8 million. LG continued its revival with 10.3 million smartphone shipments and 16.2 million handset shipments.

“The last time a major smartphone OEM showed a trend of decreasing margins combined with falling ASPs and slowing growth, BlackBerry was still on the favorable side of a large market share and revenue drop,” adds senior practice director Jeff Orr. “With major product announcements teased for Q3, Apple risks falling behind the innovation curve unless the next iPhone is more revolutionary than evolutionary.”

Hitachi Cable, Ltd. announced today that it has developed a new mass-production technology for GaN-templates, in which a high-quality gallium nitride (GaN) single-crystal thin film is grown on a sapphire substrate.

Using this product as a base substrate for an epitaxial wafer for white LEDs makes it possible to drastically improve productivity of white LED epiwafers and the LED properties. Hitachi intends for this product to become an effective solution to improve the position of white LED manufacturers in the industry, where there is severe competition.

The demand for white LEDs is rapidly expanding, and they have come to be used in backlight unit in liquid crystal displays (LCDs) and ordinary lighting devices in recent years, thanks to their energy efficiency and long service life. The structure of an white LED epiwafer consists of a thin, active layer and a p-type GaN layer with a total thickness of about 1μm over an n-type GaN layer with a thickness of about 10μm, grown on a sapphire substrate. Hitachi said all of these crystal layers are produced by the MOVPE method in ordinary manufacturing processes. The MOVPE method is suitable for growing active layers which require atomic-level control of the film thickness. Meanwhile, a disadvantage of this method is that it takes a long time to grow a high-quality and thick n-type GaN layer. White LED epiwafers can be grown about once or twice a day at the most, and thus there is a need for a high-efficiency production method.

To solve this problem, Hitachi Cable developed a GaN-template used as a base substrate for growth in the MOVPE method.

The GaN template consists of an n-type GaN layer grown on a sapphire substrate. Using a GaN-template means LED manufacturers do not need to grow an n-type GaN buffer layer and this reduces the time required for growth by about half compared with conventional methods. The GaN-templates of Hitachi Cable are also suitable for high-output LEDs which require large currents because they allow both low resistance and high crystal formation.

Hitachi Cable has developed single-crystal free-standing GaN substrates used for blue-violet lasers and developed unique HVPE-growth technology and machines for mass-production of GaN substrates. Based on this technology, Hitachi Cable developed new high-efficiency production technology and machines for mass-production of high-quality GaN-templates.

Main characteristics of GaN-template include:

  • High crystal quality and high surface quality based on growth technology established in the development of free-standing GaN substrates
  • Low resistance n-type GaN buffer which is suitable for high-output wafers and bonding-type LEDs
  • Templates on flat-surface sapphire substrates and various types of PSS (Note 4) are available
  • Wafers with 2 to 6 inches in diameters are available (8-inch version is now planned for development)

With this new GaN-template added to the lineup of GaN substrates and GaN epiwafers that it has been selling, Hitachi Cable plans to strengthen and expand its GaN product group and offer compound semiconductor products.

Dongbu HiTek today announced that it has begun volume production of Ambient Light Proximity Sensor (ALPS) chips for Clairpixel Co., Ltd., a Korean company specializing in single-chip image and motion sensor solutions for mobile, automotive, medical and security applications. Leveraging Dongbu HiTek’s specialized mixed-signal process, Clairpixel’s advanced ALPS chip is expected to target the growing Chinese smartphone market.

“Clairpixel’s ALPS chip highlights the system-on-chip attributes of our specialized 0.18um mixed-signal process,” said Jae Song, Dongbu HiTek EVP of marketing. “We look forward to expanding our collaboration before year end to add a color sensor function to this highly integrated chip design.” He credited the rapidly rising adoption rate of ALPS chips to their ability to extend battery life by optimizing screen brightness against ambient light. “With the addition of a color sensor, ALPS will also be able to automatically optimize color on large mobile screens while conserving battery power.”

According to recent market research from Gartner, Inc., worldwide smartphone shipments are expected to more than double from about 718 million units last year to more than1.6 billion units in 2016. Over this same period, Chinese smartphone shipments are forecast to rise from 25 percent to 33 percent of the total. Smart phone manufacturers such as Huawei and ZTE Corporation are expected to lead the expanding share of Chinese shipments. During the fourth quarter of 2012, some estimates report that Huawei shipped nearly 5 percent the worldwide total giving them the third largest market share worldwide

Dongbu HiTek Co., Ltd. specializes in developing s analog and mixed-signal processing technologies. The company processing portfolio encompasses Analog CMOS, BCDMOS, High Voltage CMOS, CMOS RF, CMOS Image Sensor (CIS), Display Driver IC (DDI), Touch Screen Controller IC and NOR Flash technologies.

About 1,000 of the world’s leading experts in the field of microelectronics will gather here for the 2013 Symposia on VLSI Technology and Circuits, from June 11-13, 2013 (Technology) and from June 12-14, 2013 (Circuits). The Symposia alternate between Kyoto, Japan and Honolulu, HI annually and serve as the premier mid-year gatherings to present research for the advancement of microelectronics technology and circuit development.

To foster joint interactions among device technologists and circuit/system designers, the technical programs of both Symposia will overlap for two days, and attractive joint technology-circuits focus sessions – which were successfully introduced in last year – will be held again. For a single registration fee, attendees can benefit from unique opportunities for interdisciplinary learning that cannot be replicated by other important conferences in each area.

More than 200 presentations will be given, including short courses prior to each Symposium, invited speakers addressing the industry’s most important issues, evening rump sessions spanning a range of topics at the leading edge of technology and circuit design, and a compelling luncheon talk. Also, the Symposium on VLSI Technology will be preceded by the Silicon Nanoelectronics Workshop on June 09-10, 2013 and the Spintronics Workshop on LSI in the evening of June 10, 2013.

“This year’s VLSI Technology program will highlight the breakthroughs in the evolution of SoC and More-than-Moore technologies such as advanced CMOS devices, eDRAM, new NVM’s, image sensor, and their processes (lithography, interconnects and 3D stacks), as the semiconductor industry is moving to the beyond 22nm node,” said Hitoshi Wakabayashi of Tokyo Institute of Technology, Symposium Chair of the 2013 Symposium on VLSI Technology.

“The VLSI Circuits program will present major advancements in the designs with scaled devices at and below 22nm and also with three dimensional chip stacking with TSVs, as well as more universal topics such as energy-efficient electronics, bio-medical applications, and wireline/wireless communications interfaces,” said Makoto Nagata of Kobe University, Symposium Chair of the 2013 Symposium on VLSI Circuits.

Both Symposium Chairs also expressed that: “Joint focus sessions provide excellent opportunities of close interactions among technology and circuits communities, with alignments of selected topics in a program as well as a common session room for ease of participation.”

When a team of University of Illinois engineers set out to grow nanowires of a compound semiconductor on top of a sheet of graphene, they did not expect to discover a new paradigm of epitaxy.

The self-assembled wires have a core of one composition and an outer layer of another, a desired trait for many advanced electronics applications. Led by professor Xiuling Li, in collaboration with professors Eric Pop and Joseph Lyding, all professors of electrical and computer engineering, the team published its findings in the journal Nano Letters.

Nanowires, tiny strings of semiconductor material, have great potential for applications in transistors, solar cells, lasers, sensors and more.

“Nanowires are really the major building blocks of future nano-devices,” said postdoctoral researcher Parsian Mohseni, first author of the study. “Nanowires are components that can be used, based on what material you grow them out of, for any functional electronics application.”

graphene nanowires
A false-color microscope image of a single nanowire, showing the InAs core and InGaAs shell. | Graphic by Parsian Mohseni

 

Li’s group uses a method called van der Waals epitaxy to grow nanowires from the bottom up on a flat substrate of semiconductor materials, such as silicon. The nanowires are made of a class of materials called III-V (three-five), compound semiconductors that hold particular promise for applications involving light, such as solar cells or lasers.

The group previously reported growing III-V nanowires on silicon. While silicon is the most widely used material in devices, it has a number of shortcomings. Now, the group has grown nanowires of the material indium gallium arsenide (InGaAs) on a sheet of graphene, a 1-atom-thick sheet of carbon with exceptional physical and conductive properties.

Thanks to its thinness, graphene is flexible, while silicon is rigid and brittle. It also conducts like a metal, allowing for direct electrical contact to the nanowires. Furthermore, it is inexpensive, flaked off from a block of graphite or grown from carbon gases.

“One of the reasons we want to grow on graphene is to stay away from thick and expensive substrates,” Mohseni said. “About 80 percent of the manufacturing cost of a conventional solar cell comes from the substrate itself. We’ve done away with that by just using graphene. Not only are there inherent cost benefits, we’re also introducing functionality that a typical substrate doesn’t have.”

The researchers pump gases containing gallium, indium and arsenic into a chamber with a graphene sheet. The nanowires self-assemble, growing by themselves into a dense carpet of vertical wires across the surface of the graphene. Other groups have grown nanowires on graphene with compound semiconductors that only have two elements, but by using three elements, the Illinois group made a unique finding: The InGaAs wires grown on graphene spontaneously segregate into an indium arsenide (InAs) core with an InGaAs shell around the outside of the wire.

“This is unexpected,” Li said. “A lot of devices require a core-shell architecture. Normally you grow the core in one growth condition and change conditions to grow the shell on the outside. This is spontaneous, done in one step. The other good thing is that since it’s a spontaneous segregation, it produces a perfect interface.”

So what causes this spontaneous core-shell structure? By coincidence, the distance between atoms in a crystal of InAs is nearly the same as the distance between whole numbers of carbon atoms in a sheet of graphene. So, when the gases are piped into the chamber and the material begins to crystallize, InAs settles into place on the graphene, a near-perfect fit, while the gallium compound settles on the outside of the wires. This was unexpected, because normally, with van der Waals epitaxy, the respective crystal structures of the material and the substrate are not supposed to matter.

“We didn’t expect it, but once we saw it, it made sense,” Mohseni said.

In addition, by tuning the ratio of gallium to indium in the semiconductor cocktail, the researchers can tune the optical and conductive properties of the nanowires.

Next, Li’s group plans to make solar cells and other optoelectronic devices with their graphene-grown nanowires. Thanks to both the wires’ ternary composition and graphene’s flexibility and conductivity, Li hopes to integrate the wires in a broad spectrum of applications.

“We basically discovered a new phenomenon that confirms that registry does count in van der Waals epitaxy,” Li said.

EPIC, the European Photonics Industry Consortium, has published a public database of more than 5000 company entries, an interactive map, and a report on the photonics ecosystem in Europe. With the support and contribution of numerous associations, clusters, event organizers, media organizations, and all the individuals who contributed to the survey, EPIC compiled a database of companies active in the field of Photonics. The database lists companies that manufacture photonic related equipment/materials/components/systems or extensively use photonics components, or provide services to the European photonics ecosystem. The European photonics companies are segmented by the type of systems they provide, with respectively sensing 27 percent, imaging 17 percent, transmitting information 11 percent, information storage and display 5 percent, light providing 19 percent, energy providing 6 percent, and processing 15 percent.

“One of the nice surprises of the study is the breakdown of final markets with a fairly uniform distribution, the photonics industry in Europe clearly tends to diversify” says Carlos Lee, Director General at EPIC.

The final markets are manufacturing 13 percent, lab equipment 10%, healthcare and biomedical 9 percent, life science 7 percent, automotive 6 percent, defense 6 percent, energy 5 percent, consumer electronics 5 percent, communications 5 percent and a large variety of other sectors. In addition to serving a variety of end-markets, European photonics companies are less exposed to the European crisis due to their strong exposure to foreign markets, more than 50 percent of sales are done outside Europe.

“The photonics market is terrific for Europe! The photonics companies purchase and manufacture mainly in Europe, and sell mainly outside Europe.” says Lee.

The survey also quantified Europe’s photonics employment at 377.000 people. Most companies are small, 86 percent have less than a hundred employees, but those are the ones that forecast highest growth in employment.

“The ratio turnover/staff between 150 and 250k€/employee reflects a generally high skilled workforce” says Lee.

The database, report, and map are freely available from www.epic-assoc.com/database thanks to the sponsorship of European clusters and research organizations CSEM (Swiss Center for Electronics and Microtechnology), Photonics Cluster Berlin Brandenburg, Photonics Finland, Scuola Superiore Sant’Anna (TeCIP Institute) / CNIT (Italy), SECPhO (Southern European Cluster in Photonics and Optics, and SWISSPHOTONICS.

EPIC is the industry association that promotes the sustainable development of organisations working in the field of photonics. Its members encompass the entire value chain from LED lighting, PV solar energy, Silicon photonics, Optical components, Lasers, Sensors, Displays, Projectors, Optic fiber, and other photonic related technologies.

The emerging market for Silicon Carbide (SiC) and Gallium Nitride (GaN) power semiconductors is forecast to grow a remarkable factor of 18 during the next 10 years, energized by demand from power supplies, photovoltaic (PV) inverters and industrial motor drives.

Worldwide revenue from sales of SiC and GaN power semiconductors is projected to rise to $2.8 billion in 2012, up from just $143 million in 2012, according to a new report entitled “The World Market for SiC & GaN Power Semiconductors – 2013 Edition” from IMS Research, now part of IHS. Market revenue is expected to rise by the double digits annually for the next decade, as shown in the figure below.

SiC and GaN power semiconductors

SiC Schottky diodes have been around for more than 10 years, with SiC metal-oxide semiconductor field-effect transistors (MOSFET), junction-gate field-effect transistors (JFET) and bipolar junction transistors (BJT) appearing in recent years. In contrast, GaN power semiconductors are only just appearing in the market.

GaN is a wide bandgap material that offers similar performance benefits to SiC but has greater cost-reduction potential. This price/performance advantage is possible because GaN power devices can be grown on silicon substrates that are larger and lower in cost compared to SiC.

“The key factor determining market growth will be how quickly GaN-on-silicon (Si) devices can achieve price parity and equivalent performance as silicon MOSFETs, insulated-gate bipolar transistors (IGBT) or rectifiers,” said Richard Eden, senior market analyst for power semiconductor discretes and modules at IHS. “IHS expects this will be achieved in 2019, driving the GaN power market to pass the $1 billion mark in 2022.”

SiC Schottky diode revenue exceeded $100 million in 2012, making it the best-selling SiC or GaN device currently. But even though SiC Schottky diode revenue is forecast to grow until 2015, it will decline when lower-priced 600-V GaN diodes become available. Still revenue will recover to approach $200 million by 2022, with sales concentrated at voltage ratings of 1200V and above.

By then, SiC MOSFETs are forecast to generate revenue approaching $400 million, overtaking Schottky diodes to become the best-selling SiC discrete power device type. Meanwhile, SiC JFETs and SiC BJTs are each forecast to generate less than half of SiC MOSFET revenues at that time, despite their likelihood of achieving good reliability, price and performance. End users now strongly prefer SiC MOSFETs, so vendors of SiC JFETs and BJTs have a major task ahead in educating their potential customers on the benefits of these technologies.

While IHS predicts strong growth for the SiC and GaN power semiconductor market in the years ahead, the forecast has been significantly reduced compared to the outlook from one year ago.

The main reason for the change is the reduced forecasts for shipments of equipment that use power components, resulting from today’s gloomier view of the global economy. SiC adoption forecasts also have been slashed because device prices are not falling as fast as originally assumed a year ago.

In contrast, industry confidence in GaN technology has increased, with more semiconductor companies announcing GaN development projects. For instance, Transphorm has become the first company to achieve JEDEC qualification for its GaN-on-Si devices.

In advance of the 2013 SEMICON West TechXPOTs on lithography and nonplanar transistors beyond 20nm, SEMI asked some of the speakers to comment on the challenges they wanted to highlight.

Just as a boxer avoids a surprise shot to the head or torso by using a “duck and weave” maneuver, so to must front-end technologists confront the challenges associated with extending optical lithography while planning for EUV lithography’s eventual high-productivity solution. For the industry, particularly foundries that generally need to handle multiple platforms for a variety of customers — there is the added pile-on arising from developing the two paths to accomplish control of short channel effects and leakage in transistors beyond 20nm, i.e., ultra-thin silicon-over-insulator (SOI)-based technologies and FinFETs. This year’s SEMICON West front-end processing TechXPOTs on lithography (www.semiconwest.org/node/8471) and transistors below 20nm (www.semiconwest.org/node/8481) will provide critical updates on how technologists are coping with these “contenders.” This article takes a look at challenges the industry is facing with commentary from TechXPOT speakers.

Channel Materials: A Progression of SiGe Alloys

Whether an IC manufacturer chooses to make the giant leap to 3D transistors (e.g., the Tri-gate), or takes an evolutionary approach (e.g., using SOI-based technology as a bridge), all roads lead to the implementation of 3D transistor architectures. No matter the path, however, new channel materials will have to be developed. Paul Kirsch, director of the Front-end Process Division at SEMATECH, anticipates that there will be a progressive range of Germanium (Ge) being added to Si – from perhaps 25 percent Ge up to 100 percent Ge — to form channels in pMOS FETs first, followed by nMOS FETs for logic applications.

“Industry has a great deal of experience with SiGe already,” notes Kirsch. “It’s understood how to handle that material in the fab and it’s well understood and had good performance benefits in the pMOS FET.”

What does need more attention, however, is making SiGe work for the nMOS FET — particularly for contacts and gates. Kirsch further anticipates seeing SiGe entering the roadmap between the 14nm, 10nm, and 7nm nodes, with the possibility that some IC manufacturers could start even sooner than 14nm.

A major hurdle that has to be overcome in the implementation of III-V materials is being able to engineer out the defects from the epitaxial material and the surrounding architecture of the fin to reduce the leakage current. Molecular beam epitaxy (MBE) is too expensive mainly because of its low throughput. This will mean improving what Kirsch says is the preferred process — metalorganic chemical vapor deposition (MOCVD).  In addition to engineering out defects, the industry will have to fully understand ESH issues because the source materials for this process are toxic and pyrophoric.

“That’s not to say they can’t be understood and handled safely because we have toxic and pyrophoric materials in the fab already, but every process is a little different and attention needs to be given to these materials to make sure that we are handling them very safely,” says Kirsch.

Staying with a Planar Solution

STMicroelectronics’ marketing director of Technology R&D for the Digital Sector, Giorgio Cesana, told SEMI that regardless of the many techniques to extend the technology roadmap, conventional planar bulk technology is reaching its limits.

“The last node will be 20nm because it is unable to provide the traditional speed/power gain vs. the 28nm node,” said Cesana.

To continue to follow the Moore’s Law roadmap, the industry has developed new techniques to produce fully-depleted transistors that overcome traditional bulk planar limits. There are two possibilities: stay on a planar (2D) transistor structure obtaining fully-depleted devices using a thin SOI substrate, or move to FinFET 3D structures.

“STMicroelectronics has opted for the planar solution built on a thin silicon film above a thin buried oxide layer, which is simpler to manufacture while still offering the same fully-depleted benefits,” explained Cesana.

With the company’s 28nm FD-SOI node in production, it is now focusing on the development of the next node.

“At 14nm, this will implement a set of new features for further increasing performances while optimizing power consumption and operating at reduced voltage levels.”

Test and Diagnosis at 16/14nm and Beyond

As the industry moves to 3D transistor architectures, Joe Sawicki, VP and GM of the Design-to-Silicon Division at Mentor Graphics, observes that at 16/14nm, “You’re not just dealing with scaling, you’re dealing with fundamental changes in the transistor and cell architectures. How defects will manifest themselves and behave in these new architectures is still an unknown.”

The key, he pointed out, is going after potential defects at the transistor level using a test generation technology that looks into the standard cell itself (i.e., cell-aware automatic test pattern generation (ATPG)).

“Unlike the standard test pattern generation used today that just looks at the logical boundary of the cell and tries to ensure that all the interconnects are wired correctly, cell-aware ATPG takes that one step further by looking into the standard cell transistor structures to test and ensure that all the individual transistors and the connections between them are functional.”

Though defects that might be unique to FinFET structures below 16nm are still to be determined, Sawicki explains that cell-aware ATPG is capable of defining both static and dynamic fault models on the transistor structures, as well as on the cell-internal interconnect.

“It has already been successful in finding defects at other nodes that the traditional fault models miss,” said Sawicki.

As cell-aware testing goes from 20nm to 14nm, Sawicki anticipates that the only evolution in going to the next node will be in the SPICE level model characterization to create the initial cell-aware fault models.

“Defects in FinFET transistors may cause different behaviors and require slightly different fault models to detect them,” said Sawicki. “Since the cell-aware technology starts with a transistor level cell characterization step to create the fault model, it’s expected that from a usage and ATPG process point of view, there should be little additional evolution to the technology for FinFET technology.” 

Learn more about front-end challenges at SEMICON West 2013 and hear from the experts — live!   Your registration includes free access to the exhibition hall plus all TechXPOT sessions, keynotes and executive panels. Register for SEMICON West through May 10 at no charge: www.semiconwest.org/registration

New research led by University of Cincinnati physics professors Howard Jackson and Leigh Smith could contribute to better ways of harnessing solar energy, more effective air quality sensors or even stronger security measures against biological weapons such as anthrax. And it all starts with something that’s 1,000 times thinner than the typical human hair – a semiconductor nanowire.

UC’s Jackson, Smith, recently graduated PhD student Melodie Fickenscher and physics doctoral student Teng Shi, as well as several colleagues from across the US and around the world recently have published the research paper “Optical, Structural and Numerical Investigations of GaAs/AlGaAs Core-Multishell Nanowire Quantum Well Tubes” in Nano Letters, a premier journal on nanoscience and nanotechnology published by the American Chemical Society. In the paper, the team reports that they’ve discovered a new structure in a semiconductor nanowire with unique properties.

“This kind of structure in the gallium arsenide/aluminum gallium arsenide system had not been achieved before,” Jackson says. “It’s new in terms of where you find the electrons and holes, and spatially it’s a new structure.”

These cross-sectional electron microscope images show a quantum well tube nanowire’s hexagonal facets and crystal quality (left), and electron concentration in its corners.

By using a thin shell called a quantum well tube and growing it – to about 4nm thick – around the nanowire core, the researchers found electrons within the nanowire were distributed in an unusual way in relation to the facets of the hexagonal tube. A close look at the corners of the tube’s facets revealed something unexpected – a high concentration of ground state electrons and holes.

“Having the faceting really matters. It changes the ballgame,” Jackson says. “Adjusting the quantum well tube width allows you to control the energy – which would have been expected – but in addition we have found that there’s a highly localized ground state at the corners which then can give rise to true quantum nanowires.”

The nanowires the team uses for its research are grown at the Australian National University in Canberra, Australia – one partner in this project that extends to disparate parts of the globe.

The team’s discovery opens a new door to further study of the fundamental physics of semiconductor nanowires. As for leading to advances in technology such as photovoltaic cells, Jackson says it’s too soon to tell because quantum nanowires are just now being explored. But in a world where hundreds of dollars’ worth of technology is packed into a 5-by-2.5 inch iPhone, it’s not hard to see how small but powerful science comes at a premium.

The team at UC is one of only about a half dozen in the US conducting competitive research in the field. It’s a relatively young discipline, too, Jackson says, and one that’s moving fast. For such innovative science, he says it’s important to have a collaborative effort. The team includes scientists from research centers in the Midwest, the West Coast and all the way Down Under: UC, Miami University of Ohio and Sandia National Laboratories in California here in the US; and Monash University and the Australian National University in Australia.

 “We’re training students in state-of-the-art techniques on state-of-the-art materials doing state-of-the-art physics,” Jackson says. “Upon completing their education here, they’re positioned to go out and make contributions of their own.”

Additional contributors to the paper are Jan Yarrison-Rice of Miami University, Oxford, Ohio; Bryan Wong of Sandia National Laboratories, Livermore, Calif.; Changlin Zheng, Peter Miller and Joanne Etheridge of Monash University, Victoria, Australia; and Qiang Gao, Shriniwas Deshpande, Hark Hoe Tan and Chennupati Jagadish of the Australian National University, Canberra, Australia.

The critical processes and technologies necessary to continue Moore’s Law are currently more uncertain than ever before in the history of advanced semiconductor manufacturing. To assess these uncertainties and provide the latest information on EUV lithography, 3D transistors, 450mm wafer processing, and other challenges to preserving the pace of Moore’s Law, the leading authorities on these crucial issues will provide their insights, perspectives and predictions at SEMICON West (www.semiconwest.org), held from July 9-11 in San Francisco, Calif.  Free Registration for SEMICON West 2013 ends on  May 10 — register now: www.semiconwest.org/registration.

Although progress to take EUV lithography into the realm of high-volume manufacturing continues to be made, the readiness of source technologies, mask infrastructure and resist performance are still not known with a high degree of certainty. Until EUV Lithography is ready for high-volume manufacturing, the industry will continue to rely on double-patterning and even multiple-patterning lithography schemes using 193 immersion technology to take it beyond 22nm. How the industry will address these barriers, uncertainties and alternatives will be the focus the lithography session at SEMICON West.

The mobile market is driving the move to novel transistor architectures that offer greater performance and power benefits than traditional planar architectures. Memory and logic manufacturers are pursuing different strategies including leveraging innovations in design rules, new channel materials and processes (e.g., MOCVD) and inspection and metrology challenges.

While materials, architecture and processing technologies are undergoing revolutionary change, wafer processing platforms are also being radically transformed with a planned transition to 450mm wafers. For chip manufacturers and suppliers, this will involve increased levels of collaboration, further advancements in tool prototypes, and increased visibility into related supply chain implications.  The SEMICON West 450 Transition Forum will provide the latest updates on the status of 450 R&D, as well as a review of key technology considerations and a discussion of implications and opportunities for the supply chain.

Each of these programs will take place in the TechXPOT conference sessions on the exhibit floor.  Other TechXPOT programs include sessions on 2.5D and 3D IC Packaging, Productivity Innovation at Existing 200mm/300mm Fabs, Silicon Photonics, Lab-to-Fab Solutions, MEMS, LED Manufacturing, and Printed and Flexible Electronics.  SEMICON West will features over 50 hours of free technical, applications and business programs with the critical, need-to-know information presented by industry leaders.  .

SEMI is the global industry association serving the nano- and microelectronics manufacturing supply chains. SEMI maintains offices in Bangalore, Beijing, Berlin, Brussels, Grenoble, Hsinchu, Moscow, San Jose, Seoul, Shanghai, Singapore, Tokyo, and Washington, D.C.