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BY PETE SINGER, Editor-in-Chief

China has become the largest and the fastest growing market in the world. 40% of the worldwide semiconductor shipments go to China and that’s expected to increase to almost 42% in 2019.

The “National Semiconductor Industry Development Guidelines” and “Made in China 2025” were published by China’s State Council in June 2014 and May 2015, respectively. Both policies have already led to a major push in the development of the local IC industry, with investments in semiconductor memories, design, foundries, OSATS, and equipment and materials.

Based on the “National Semiconductor Industry Development Guidelines,” a US$19 billion national industry investment fund has been set up to help local foundries finance the build-up of advanced manufacturing processes, and also to assist local IC firms to form mergers and/or make acquisitions internationally. Dieter Ernst, a Senior Fellow at the East West Center In Hawaii says with this plan, China seeks to move from the catching up stage to a full-scale forging ahead.

With the “Made in China 2025” initiative, China is aiming to improve the self-sufficiency rate for ICs in the nation to 40% in 2020, and boost the rate further to 70% in 2025.

What will be key is how Chinese companies can gain access to 16/14nm, 10nm, and 7nm technologies as well as DRAM and 3D NAND technologies.

According to Handel Jones of IBS, who spoke at SEMI’s Industry Strategy Symposium earlier this year, China is also strongly positioned in 5G. “China will be the global leader in 5G,” he said. Based on an analysis of Huawei, Ericsson, Nokia and others, Jones said Huawei – which is investing about $1 billion/year — is ahead. “That’s going to have a fairly disruptive effect on the supply chain,” he said. He expects early development in 2017/2018 and then fairly extensive deployment in 2020.

In a recent report, “From Catching Up to Forging Ahead: China’s Policies for Semiconductors,” Ernst points out that while the opportunities for China are real, they all involve considerable uncertainty. “Basic parameters that determine how China will fare may change at short notice and in unpre- dictable ways,” he said. To succeed, China needs to move toward a bottom-up, market-led approach.

TSMC today announced that the Company and the municipal government of Nanjing, China have signed an investment agreement. This agreement affirms that TSMC will make an investment in Nanjing valued at US$3 billion to establish TSMC (Nanjing) Co. Ltd., a wholly-owned subsidiary managing a 12-inch wafer fab and a design service center.

TSMC’s 12-inch fab site in Nanjing will be located in the Pukou Economic Development Zone. Planned capacity is 20,000 12-inch wafers per month, and the facility is scheduled to commence production of 16nm process technology in the second half of 2018.

As a technology leader, TSMC began volume production of 16nm process technology for customers in 2015, and accounted for more than half of the global foundry market for production of 14/16nm technology wafers in that year. Further significant increases in global foundry market share of the 14/16nm technology production is forecast for 2016. TSMC also holds the largest foundry market segment share in China with more than 100 Chinese customers.

“With our 12-inch fab and our design service center in Nanjing, we aim to provide closer support to customers as well as expand our business opportunities in China in step with the rapid growth of the Chinese semiconductor market over the last several years,” said TSMC Chairman Dr. Morris Chang. “We look forward to stronger collaboration with our customers to further expand our market share in China.”

A look into how the silicide process has evolved over the years, trying to cope with the progress in scaling technology and why it could no longer be of service to finFET devices.

BY ARABINDA DAS, TechInsights. Ottawa, Canada

Samsung and TSMC introduced their finFET devices in 2015 and joined Intel as the semiconductor industry’s three major manufacturers possessing the most advanced technology. Intel’s 14nm finFET 5Y70 processor was commercialized in 2014 and within six months Samsung mass produced their 14nm finFET Exynos 7 7420 SoC. Later that same year, TSMC started supplying their 16nm finFET based devices to Apple. Today Samsung and TSMC both supply their finFET based processors to Apple, which are being used for the iPhone6’s A9 processor.

Since the release of the iPhone6 several blogs and articles have been written about the cost of fabrication, the perfor- mance of tri-gates, the type of work-function materials used by the manufacturers, the dominant supplier for Apple and speculation about the future of finFET devices. TechInsights has performed detailed structural analyses of these three devices and has also tried to understand some of these questions. While comparing these structural reports on finFET devices, one small detail stands out is that a major pillar of semiconductor processing is missing. The silicide process is not being used. Intel stopped using the silicide process in their 22nm finFET “Ivy Bridge” Processor. Samsung and TSMC at 20nm used the existing planar structure and employed NiSi on top of their source and drain regions. But as soon as these two device makers adopted finFET structure in 14 and 16nm nodes they abandoned the thirty year old silicide process. It is interesting to look into how the silicide process has evolved over the years, trying to cope with the progress in scaling technology and finally also why it could not anymore be of service to finFET devices.

The silicide process has been an integral part of semicon- ductor manufacturing since the early 1980s. The first patents were filed by Motorola, Fairchild and IBM. This process is used as an interface between semiconductor material and metals to reduce the contact resistance between tungsten contacts and the source-drain regions or the gate electrode. This parasitic resistance should be minimized to enable higher drive currents in transistors. Silicides have metal-like properties and are made by reacting Si to refractory or near-noble metals. A large number of metals in the periodic table can form silicides. The most common silicides in the semiconductor industry are titanium silicide, tungsten silicide, cobalt silicide, nickel silicide and nickel-platinum silicide. Platinium was used to stabilize the NiSi phase at a specific temperature.

These compositions can exist in various phases and have unique phase diagrams. One particular integration process of silicides, known as self-aligned silicides (also termed ‘salicide’), has played a significant role in bipolar devices, passives and in CMOS devices. In this scheme, no additional mask is needed; the silicide is grown on exposed silicon or polysilicon surfaces and not at all on neighboring dielectric surfaces.

The main steps of growing the silicide are depositing a refractory metal or a near-noble metal on the exposed Si and then annealing in a non-oxidizing atmosphere at a suitable temperature to react the metal with Si. The duration of the thermal cycle should be long enough to convert the majority of the metal to a silicide composition. Several stages of annealing may be completed to stabilize the phase. Thereafter the unreacted metal is removed by wet-etching. For a detailed understanding of silicide process please refer to the book “Silicide technology for integrated circuits” by L.J. Chen or to the lecture notes from Professor Sarsawat from Stanford University [1].

The earliest image of the silicide process in TechInsights’ database is from Intel’s 166 Mhz Pentium microprocessor A80502166 based on a 0.35 μm CMOS process. The die markings of this device suggest that it was made in 1992-93. FIGURE 1 shows a TEM cross-section of a gate employing titanium silicide. The transistors in this device have 0.40 μm thick titanium silicide on top of the gates and silicided diffusions formed using a salicide process.

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The industry realized very quickly that TiSi2 was not easily scalable. It has two phases C49-TiSi2 and C54-TiSi2. The first is formed at temperatures between 350 to 700o C and has a resistivity of 60-80 μΩcm; while the other is formed around 750 ̊ C and has a resistivity lower than C49-TiSi2 (~20 μΩcm). As devices scaled down it became necessary to reduce the thermal budget which had the consequence of forming C49-TiSi2 instead of C54-TiSi2, which resulted in higher contact resistance. Since this was counter-productive, it was time to switch to a new silicide. Intel’s Pentium III “Tualatin” used Co-silicide in a 0.13 μm CMOS process (FIGURE 2).

The next major milestone for silicide processes came at the 90nm node when Intel introduced the concept of raised source and drain for the PMOS transistor in their “Prescott” processor. The raised source and drain regions were formed by etching out portions of the Si substrate at the source and drain regions and then depositing epitaxial layers of Si1-xGex, where x is between 0 and 1. The etching out used both dry and wet chemistry. This concept was an innovative use of the growth rate variability on the bottom surface and on the side walls of the cavity due to the different crystal plane orientations of the silicon substrate. SiGe has a lattice constant that is slightly larger than that of silicon so this epitaxial film induces a large uniaxial compressive strain in the PMOS channel region, resulting in significant hole mobility improvement. But SiGe surfaces were not very suitable for Co-Silicide. Most silicides have much lower free energy than germanides so when the silicide is formed on a Si-Ge alloy the Ge is expelled. This expelled Ge undergoes agglom- eration and increases the contact resistance thus negating the effect of the enhanced mobility. The use of Ni instead of Co was especially beneficial for salici- dation of both Si and SiGe source drain regions because Ni provides a more uniform contact resistance. Moreover, NiSi has the same resistivity as CoSi2 but has smaller Si consumption. FIGURE 3 shows Intel’s 90nm “Prescott” transistor along with NiSi on top of SiGe regions.

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NiSi was the mainstream process for two process nodes (90nm and 65nm) and was employed on top of polysilicon gate as well as on top of the source-drain regions. Around the year 2000, there were even discussions about a fully silicided (FuSi) gate. Then in 2008 Intel introduced the high-k dielectric and metal gate-last (HKMG) process at the 45nm node in their “Penryn” processor. This device did not require any more silicide on top of the gate but only at the source-drain regions. FIGURE 4 shows a TEM cross-section of Intel’s 45nm “Penryn” processor. In these devices, silicide is formed only on top of source and drain regions. The silicide is self-aligned to the sidewall spacer. The surface of the SiGe source-drain regions that is in contact with the silicide has enriched Si concentration to facilitate the silicide process. The nickel silicide depth from the silicon surface is about 65nm.

Screen Shot 2016-03-25 at 1.50.45 PM

Finally, in 2012 Intel commercialized the first finFET device at 22nm in their “Ivy Bridge” (Intel core i5-3550) processor, in this device the silicide process was abandoned. To understand why the silicide process was not employed, it is important to grasp the differences between a tri-gate device and a planar device. Tri-gate brought in several advantages. For example, the effective gate width is proportional to the fin height and can be increased without increasing the device footprint. Additionally, because the gate wraps around the fin, there is better control of the channel. Another benefit is that the walls of the fin offer a different crystallographic plane than the top of the fin. Here, in this integration schemethe PMOS transistors benefit from higher mobility along the fin sidewalls.

The tri-gate integration scheme also brought in several process challenges. Epitaxial SiGe for PMOS and epitaxial Si islands for NMOS must be grown in a recess in a narrow Si fin rather than in the Si substrate. One constraint is due to double patterning, which requires that all the fins be of the same width and pitch; so if a larger gate width is required then multiple fins have to be employed. That means that the gate width is dependent on integer units of fins. This concept of integer units of fins is well illustrated in FIGURE 5, where the I/O transistor of TSMC finFET is shown having several fins connected in parallel.

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Multiple fins connected in parallel imply that the contact to the source-drain regions must have exactly the same contact resistance on multiple fins and this was indeed difficult to guarantee with the silicide process due to the vagaries of the diffusion process. In the Ni silicide process, it is believed that Ni atoms are the dominant diffusing species in Ni monosilicide formation; this property can lead to excessive silicidation on narrow lines. Ni-silicide is sensitive to temperature and often at low temperature a NiSi2 is formed. This phase is usually seen on strained PMOS structures and can create an increase of contact resistance. Non uniform distribution of silicide process was the biggest show-stopper for this old process.

In addition to the silicide process there was also the problem of dopants in the source and drain regions. The thermal process causes undesirable dopant diffusion and leads to the loss of the junction abruptness. Also, thermal processes create thermal budget issues in the integration’s process flow. There could be also other reasons for avoiding the silicide process in finFET devices, like leakage and stress because it is well known that the silicide process has an impact on device properties. Luckily, the technology of in-situ doping was already mature and used for DRAM devices as these volatile memories do not require a silicide process due to leakage concerns. Intel in its 22 nm process flow, most likely used in-situ doping of epitaxial regions along with trench contacts to eliminate the silicide process. This does not mean that other doping techniques like implants and thin film doping were not employed; they were probably used during different parts of the process flow. Intel did mention at IEDM 2014 that thin film doping method was used for 14nm finFET devices.

The introduction of trench contact, which ensure equal and low contact resistance to multiple fins was the ultimate reason not to use the silicide process in FinFETs. The integration flow is described in FIGURE 6. First, multiple parallel fins are formed. Each fin is separated from its neighbors by the STI-oxide. On these fins a sacrificial poly-silicon gate structure is made that runs perpendicular to the fins. On portions of the fin not covered by the gate, cavities are etched by using a line mask or a self-aligned process. Recesses in the fins are made by selectively etching the silicon. In-situ doped epitaxial layers are then grown to form source-drain regions. These epitaxial layers extend beyond the fin width and may even merge to form a continuous layer. The epitaxial layers do not extend above the surface of the fin. Subsequently, the poly-silicon gate is removed and the high-k-metal-gate (HKMG) formed in its place. A dielectric layer is deposited on top of the gates and the fins. The dielectric layer is patterned to form trenches running parallel to the gate. The integration scheme further includes etching a trench in the epitaxial layers and then filling the trench with tungsten to form trench contacts.

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FIGURE 7 shows the cross-sectional schematic diagram of how the trench contacts are embedded or well anchored in the epitaxial layers.

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Cross-sectional images parallel to the fins of the three 1x node finFETs from Intel, Samsung and TSMC are collected in FIGURES 8a, 8b and 8c, respectively. The cross-section is made along one of the fins. The important point to note is that the trench contact at the surface of the source and drain regions is surrounded on three sides. It is more pronounced in the case of Samsung’s device. The tungsten metal lines that run parallel to the gate, form the contacts for source-drain regions and are well anchored in the epitaxial layers. This increases the surface area of the contact and reduces the contact resistance.

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FIGURE 9 shows the cross-section of the 16nm finFETs from TSMC in the direction perpendicular to the fins. In this direction the epitaxial regions could be designed to merge or extend beyond the fin width and thus increase the contact region with the metal contact. This increased contact region reduces the contact resistance.

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The silicide process has a long history in the semicon- ductor industry; it has evolved through many phases from tungsten silicide to titanium silicide to cobalt-silicide to nickel silicide. But it could not be used for finFET devices. As for these devices, multiple fins may be used to form a single transistor, which implies that the contacts to all these fins have the exact same contact resistance. This is difficult to control in a process that is purely based on diffusion like the silicide process. So after 30 or more years of service it is time that the silicide process takes retirement and leaves the future to trench contacts and in-situ doping; however, there is always a possibility its use may be prolonged especially if the silicidation can be localized only inside the trench contact and not over the entire surface of the source-drain regions. Trench contacts will most likely be used in the next 10nm node but sub 10nm node, if new concepts like nanowire or new materials are introduced, the semiconductor industry is likely to innovate some other designs.

ARABINDA DAS is a Senior Process Analyst in the Technical Services division of TechInsights, Ottawa, Canada, [email protected]

2015 was a significant year for the GaN RF industry: within the new technology and market report, GaN RF Devices Market: Applications, Players, Technology, and Substrates 2016 – 2022 report, Yole Développement (Yole) analysts highlighted the dramatic increase in wireless infrastructure market sales driven by the massive adoption of LTE networks in China. By year’s end, the total RF GaN market was close to US$300 million. GaN RF devices market will double over the next five years, led by GaN’s adoption across various market segments.

This new GaN RF report from Yole, describes the GaN’s presence and development scheme in different markets including wireless infrastructure, defense and aerospace, satellite communication, wired broadband and other ISM band applications. The “More than Moore” market research and strategy consulting company, Yole proposes a complete analysis covering different emerging GaN players and more than 600 GaN devices developed and implemented in such applications as radar, base transceiver station, CATV, VSAT and jammers. This report also includes a detailed analysis of the different scenarios related to GaN-on-SiC and GaN-on-Si developments beyond 2020.

gan rf graph

Sales will likely not soar as high over the next two years, but growth will continue, mainly driven by increased adoption of GaN technology in the wireless infrastructure and defense markets. A significant boost will occur around 2019 – 2020, led by the implementation of 5G networks.

“Market size will be multiplied by 2.5 by the end of 2022, posting a CAGR of 14% from 2016 – 2022,” explained Dr Hong Lin, Technology & Market Analyst at Yole.

The wireless infrastructure and defense markets are the reason of this success: both market segments offer great opportunities for GaN technology. Wireless infrastructure, having surpassed defense is now representing more than half of GaN’s total market. According to Yole’s analysts, this positive evolution will continue growing fast at an expected 16% CAGR between 2016 and 2022.

“Though GaN was originally developed to support governmental military and space projects, mainstream commercial markets should fully embraced this novel technology as well,” commented Zhen Zong, Technology & Market Analyst at Yole.

GaN’s increased implementation in base stations and wireless backhaul stems from the growing demand for data traffic and higher operating frequencies and bandwidths. In future network designs, new technologies like carrier aggregation and massive MIMO will actually put GaN in a superior position compared to existing LDMOS. GaN products have not yet covered the wireless infrastructure market’s full spectrum, and we see more opportunities in the higher-frequency range. When looking at different players’ products, most GaN players offer similar products for base station applications ranging from 800MHz – 3.5 GHz. The competition will no doubt grow fiercer, and the cake, even if it’s a fast-growing one, will not be divided equally for everyone. In 2016, new entrants like Infineon and possibly another LDMOS player will bring more uncertainty. In the meantime, defense remains another important market for GaN, and more and more new products and designs are benefiting from GaN’s superior performance and design simplification. Within its GaN RF devices report, Yole predicts a steadily-growing penetration rate for GaN in defense market applications like IED jammers, military communications, radar, electronic warfare, and more.

The Critical Materials Conference, a pivotal, 2-day event organized by TECHCET with the support of the Critical Materials Council, will be held this year in Hillsboro, Oregon on May 5th and 6th, directly following the Council Meeting. Industry experts from leading semiconductor fabricators, materials companies, and market research firms will present insights into the dynamic, and sometimes volatile, topic of semiconductor process materials and markets, including actionable-information on materials and supply-chains, for current and future semiconductor manufacturing strategies.

Speakers will also address critical materials used in HVM fabs plus manufacturing integration issues associated with new and existing materials that impact future devices. Conference presentations will include details on materials and technology considerations for IC fabrication.

Go to www.cmcfabs.org/seminars/ to register, or contact [email protected].

The Critical Materials Council for Semiconductor Fabricators (CMC Fabs) is a unit of TECHCET CA LLC, a corporation focused on process materials supply chains, electronic materials technology, and materials market research consulting for the semiconductor, display, solar/PV, and LED Industries. Since 2000, TECHCET has produced the annual Critical Material Reports for SEMATECH and the Critical Materials Council.

North America-based manufacturers of semiconductor equipment posted $1.26 billion in orders worldwide in February 2016 (three-month average basis) and a book-to-bill ratio of 1.05, according to the February EMDS Book-to-Bill Report published today by SEMI.  A book-to-bill of 1.05 means that $105 worth of orders were received for every $100 of product billed for the month.

SEMI reports that the three-month average of worldwide bookings in February 2016 was $1.26 billion. The bookings figure is 3.7 percent lower than the final January 2016 level of $1.31 billion, and is 3.9 percent lower than the February 2015 order level of $1.31 billion.

The three-month average of worldwide billings in February 2016 was $1.20 billion. The billings figure is 1.3 percent lower than the final January 2016 level of $1.22 billion, and is 5.9 percent lower than the February 2015 billings level of $1.28 billion.

“The book-to-bill ratio has remained at or above parity for three months in a row,” said Denny McGuirk, president and CEO of SEMI. “The data indicate an improved spending trend in the second half of the year, driven by 3D NAND and 10nm investments.”

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

Billings
(3-mo. avg)

Bookings
(3-mo. avg)

Book-to-Bill
September 2015

$1,495.0

$1,554.9

1.04
October 2015

$1,358.6

$1,325.6

0.98
November 2015

$1,288.3

$1,236.6

0.96
December 2015

$1,349.9

$1,343.5

1.00
January 2016 (final)

$1,221.2

$1,310.9

1.07
February 2016 (prelim)

$1,204.8

$1,262.4

1.05

Source: SEMI (www.semi.org), March 2016

The semiconductor IP market is expected to reach $7.01 billion USD by 2022 from USD 3.09 Billion in 2015, at a CAGR of 10.55% between 2016 and 2022, according to the newly released report “Semiconductor (Silicon) IP Market by Form Factor (Integrated Circuit IP, SOC IP), Design Architecture (Hard IP, Soft IP), Processor Type (Microprocessor, DSP), Application, Geography and Verification IP – Forecast & Analysis to 2022”, published by MarketsandMarkets.

The driving factors for the growth of this market include increasing demand for advanced SoCs in the consumer sector, increased funding from governments and investors, emerging IoT ecosystem, recovering automotive sector, and growing popularity of miniaturized devices.

SoC IP had the largest market in 2015

Increase in the demand of smarter and power-efficient electronic devices, demand for multi-core technologies and embedded graphics are the major driving factors for the SoC market. SoCs are being utilized by all smart devices currently, such as smart phones, communication equipment, next-gen automotive, and electrocardiogram (ECG) telemetry devices. The increasing demand for energy efficient devices has led to development of newer SoCs which are more compact in size, faster response time than their predecessors and even consumes much lesser power. Moreover, the increased demand for multi-core technologies and embedded graphics has led to development of advanced SoCs.

Embedded processor IP devices expected to led the semiconductor processor IP market during the forecast period

Increasing demand for pervasive M2M (machine-to-machine) connectivity and a rich user experience across industries has spurred new opportunities for growth in both traditional and emerging embedded processor market. Emerging multi-core processors such as quad-core and octa-core for enhanced real-time experience in smart consumer electronics such as smartphones and smart wearables is expected to drive the embedded processor IP market.

The mobile & tablets segment expected to dominate the semiconductor IP market during the forecast period

A Strong consumer demand for smartphones, tablets, and other mobile devices is fueling significant growth within the semiconductor industry, and the rush to develop differentiated and powerful mobile solutions is driving rapid change within the entire ecosystem. Mobile phones and tablets have become the necessity of every individual which has increased the demand for the same; this is expected to drive the semiconductor IP market. Key players in the market such as Synopsys (U.S.), ARM (U.K.), and Rambus (U.S.) design chips exclusively to cater this application sector because of its growth potential.

The market in APAC expected to grow at the highest CAGR during the forecast period 

APAC is expected to hold the largest share of the semiconductor IP market by 2022. The major reasons for this are the governments in ChinaTaiwan, and Japan are actively attempting to boost the domestic semiconductor market and assist local companies in expanding their business globally; Chinese consumers and companies are becoming increasingly important to the growth of the global semiconductor market; increased funding from both government and private sources, is leading to merger, acquisition, investment, and partnership opportunities worldwide.

SEMI, the global industry association for companies that supply manufacturing technology and materials to the world’s chip makers, today reported that worldwide sales of semiconductor manufacturing equipment totaled $36.53 billion in 2015, representing a year-over-year decrease of 3 percent. 2015 total equipment bookings were 5 percent lower than in 2014. The data are available in the Worldwide Semiconductor Equipment Market Statistics (WWSEMS) Report, now available from SEMI.

Compiled from data submitted by members of SEMI and the Semiconductor Equipment Association of Japan (SEAJ), the Worldwide SEMS Report is a summary of the monthly billings and bookings figures for the global semiconductor equipment industry. The report, which includes data for seven major semiconductor producing regions and 24 product categories, shows worldwide billings totaled $36.53 billion in 2015, compared to $37.50 billion in sales posted in 2015. Categories cover wafer processing, assembly and packaging, test, and other front-end equipment. Other front-end includes mask/reticle manufacturing, wafer manufacturing, and fab facilities equipment.

Spending rates increased for Taiwan, Korea, Japan, and China, while the new equipment markets in North America, Rest of World, and Europe contracted. Taiwan remained the largest market for new semiconductor equipment for the fourth year in a row with $9.64 billion in equipment sales. The expanding markets in South Korea and Japan surpassed the North American market, to claim the second and third largest markets, respectively, while North America fell to fourth place at $5.12 billion. The China market remained larger than the Rest of World and European markets.

The global other front end segment increased 16 percent; the wafer processing equipment market segment decreased 2 percent; total test equipment sales decreased 6 percent; and the assembly and packaging segment decreased 18 percent.

Semiconductor Capital Equipment Market by World Region (2014-2015)

2015

2014

% Change
Taiwan

9.64

9.41

2%
South Korea

7.47

6.84

9%
Japan

5.49

4.18

31%
North America

5.12

8.16

-37%
China

4.90

4.37

12%
Rest of World

1.97

2.15

-9%
Europe

1.94

2.38

-19%
Total

36.53

37.50

-3%

Source: SEMI/SEAJ March 2016; Note: Figures may not add due to rounding.

Nanoelectronics research center imec has today announced the opening of its new 300mm cleanroom. With this 4000m2 new facility, imec’s semiconductor research cleanrooms now totals 12,000m2, one of the most advanced research facilities in the world dedicated to scaling IC technology beyond 7nm. This facility will enable imec to keep its global leading position as a nanoelectronics R&D center serving the entire semiconductor ecosystem.  Its global partners including foundries, IDMs, fabless and fablite companies, equipment and material suppliers, will benefit from topnotch semiconductor processing equipment (including alfa and beta tools) to develop innovative solutions for more powerful, high-performing, cheaper and energy-efficient ICs, which are crucial in the evolution of the Internet of Everything and a sustainable digital future.

Extending the existing cleanroom, the new facility complies with the newest standards in the semiconductor industry, and provides additional space for the most advanced tools that will lead innovations in new device and system concepts. Installations of the first tools began in January 2016. The new 300mm cleanroom complements imec’s other production facilities including its bio-nanolabs, neuroelectronics labs, imaging and wireless and electronics test labs, photovoltaic pilot lines, and GaN-on-Si, Silicon photonics and MEMS pilot lines.

“Since our founding in 1984, imec has become the world’s largest independent nanoelectronics research center with the highest industry commitment,” stated Luc Van den hove, president and CEO at imec. “This success is the result of the unique combination of our broad international partner network, including the major global players of the semiconductor industry, top scientific and engineering talent, and imec’s one of a kind infrastructure. The extension of our cleanroom provides our partners with the necessary resources for continued leading edge innovation and imec’s success in the future within the local and global high-tech industry.”

The cleanroom was constructed by M+W, an internationally renowned contractor of  large-scale high-tech infrastructure. The construction was completed in 20 months, and includes a  reflecting facade, from Architect Stéphane Beel, which is intended to integrate the building with the environment. The new cleanroom comprises a total investment (building and equipment) of more than 1 billion euro of which 100 million euro funding from the Flemish Government and more than 900 million euro investments from joint R&D with the leading players from the entire semiconductor industry, totaling more than 90 industrial partners.

new imec center

Semiconductor Manufacturing International Corporation and Crossbar, Inc. jointly announced today that they had signed a strategic partnership agreement on non-volatile RRAM development and production.

As part of the partnership, SMIC and Crossbar have signed an agreement to provide RRAM blocks based onSMIC’ 40nm CMOS manufacturing process. This will enable customers to integrate low latency, very high performance and low power embedded RRAM memory blocks into MCUs and SoCs, targeting the Internet of Things, wearable and tablet computers, consumer, industrial and automotive electronics markets.

“Crossbar continues to execute on schedule, and is now entering the licensing phase. We are honored to announce the collaboration with SMIC as a major stepping stone towards the commercialization of our RRAM technology,” said George Minassian, CEO and co-founder of Crossbar. “Designers of highly integrated MCUs and SoCs need non-volatile memory technologies that are easy to integrate into their products and can be manufactured using standard CMOS logic processes. Crossbar RRAM technology and SMIC manufacturing expertise are creating a new era of unique memory architectures with tighter security, lower power consumption while providing more capacity and fast access time.”

Crossbar RRAM’s CMOS compatibility and scalability to small process geometries enables the integration of non-volatile memory blocks at the same process nodes of MCUs and SoCs.  RRAM cells are integrated in standard CMOS processes between two metal lines of standard CMOS wafers. This enables extremely integrated solutions with on-chip non-volatile memory, processing cores, analog and RF combined on a single die.

“Based on SMIC’s 40nm process node, wecanoffer high-capacity and low-power memory technology with unique security features for smartcards and various IoT devices to customers.” said Dr. Tzu-Yin Chiu, Chief Executive Officer and Executive Director of SMIC. “We’re delighted to have Crossbar as a new partner in our stable and reliable 40nm technology platform. We are able to support global customers with competitive technology and help them shorten time to market. We’ll continue to attach great importance to long-term strategic cooperation with more world-leading companies to better serve the market and achieve win-win situation in the future.”

Crossbar’s RRAM provides a cost-effective integrated memory solution for embedded applications requiring low power, high performance non-volatile code execution and data storage.