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Research and Markets’ recent report, “Global Semiconductor Packaging Materials Market 2016-2020”, expects the global semiconductor packaging materials market to grow at a CAGR of 4.79% during the period of 2016-2020.

The report covers the present market and the growth prospects of the global semiconductor packaging materials market for the period 2016-2020. To calculate the market size and geographical segmentation, the report considers the revenue generated from the sales of different types of packaging based on the type of material, which can be broadly classified as either leadframe based or laminate substrate based.

Market Challenges, Drivers and Trends

The semiconductor industry is facing many changes in technology, including the introduction of 3D ICs, including 3D NAND, FinFETs, and stacked dies. The increase in demand for multifunctional and high-performance ICs in electronic devices is driving the need for regular technological upgrades. 3D ICs are an ideal solution to meet the growing demand for smaller and higher-performance ICs in the consumer electronics segment. 3D NAND is another technology that provides a large memory storage area in minimal space; this technology will likely capture 54.82% of the total NAND market by the end of 2020.

According to the report, the demand for polymer adhesive wafer bonding equipment is rising due to the increasing adoption of advanced packaging applications like TSV, 2.5D and 3D ICs, stacked die packaging, and MEMS packaging. Polymer adhesive wafer bonding equipment provides reliable thinning and backside processing of the stacked dies. In addition, it lowers the cost of TSV (through-silicon via) integration. The rising demand for polymer adhesive wafer bonding equipment will, therefore, have a moderately high impact on the market for semiconductor devices as this equipment supports 3D packaging, which is the future of the semiconductor packaging and assembly industry.

Further, the report states that the currency fluctuation in countries such as China and Japan negatively affects the growth of semiconductor packaging materials market

Cypress Semiconductor Corp. (Nasdaq:  CY) and Broadcom Limited (Nasdaq:  AVGO) today announced the signing of a definitive agreement under which Cypress will acquire Broadcom’s Wireless Internet of Things (IoT) business and related assets in an all-cash transaction valued at $550 million. Under the terms of the deal, Cypress will acquire Broadcom’s Wi-Fi, Bluetooth and Zigbee IoT product lines and intellectual property, along with its WICED brand and developer ecosystem. Broadcom’s IoT business unit, which employs approximately 430 people worldwide, generated $189 million in revenue during the last twelve months. The acquisition strengthens Cypress’s position in key embedded systems markets, such as automotive and industrial, and establishes it as a leader in the high-growth consumer IoT market, a segment that includes wearable electronics and home automation solutions.

The transaction, which has been approved by the board of directors of Cypress and Broadcom, is expected to close in the third calendar quarter of 2016, subject to customary conditions and regulatory approvals. Cypress expects the transaction to be accretive within a year of closing and to improve its gross margin, earnings and long-term revenue potential.

“Cypress is a significant player in the IoT today because of our ultra-low-power PSoC programmable system-on-chip technology, but we’ve only been able to pair it with generic radios so far. Now we have the highly regarded Broadcom IoT business—Wi-Fi, Bluetooth and Zigbee RF technologies—that will transform us into a force in IoT and provide us with new market opportunities as well,” Cypress President and CEO T.J. Rodgers said. “What we bring to the party is over 30,000 customers worldwide who need advanced, ultra-low-power wireless communication but only can absorb it in the form of an easy-to-use programmable embedded system solution.”

“We are thrilled to be joining forces with Cypress to address the fast growing IoT market,” Broadcom IoT General Manager Stephen DiFranco said. “With our IoT connectivity products, Cypress will be able to provide the connectivity; the MCU, system-on-chip, module and memory technologies; and the mature developer ecosystem that IoT designers require, creating an end-to-end portfolio of embedded solutions and a single IoT design platform.”

Under the terms of the deal, Broadcom will continue to focus on its wireless connectivity solutions for the access and mobility segments that are not IoT related, including serving set-top box, wireless access, smartphone, laptop and notebook customers. Cypress will capitalize on the rapidly growing Wi-Fi and Bluetooth connectivity (17% per year1) markets in consumer, industrial and automotive IoT segments.

“The robust, ready-to-scale WICED brand and developer network of module makers, value-added resellers (VARs), technology partners and ODMs who are already working with its technology will give us immediate revenue growth capability in new channels,” Rodgers said. “Cypress will continue to support and grow this network and to provide it with future generations of innovative, disruptive connected products. Cypress will also bring these new technologies to the automotive market, where we are already No. 3 worldwide in microcontrollers and memories, and where the connected car boom has just started.”

Greenhill & Co., LLC served as lead financial advisor, Bank of America Merrill Lynch served as financial advisor and is providing committed debt financing, subject to customary conditions, and Wilson Sonsini Goodrich & Rosati acted as legal counsel to Cypress for this transaction.

North America-based manufacturers of semiconductor equipment posted $1.38 billion in orders worldwide in March 2016 (three-month average basis) and a book-to-bill ratio of 1.15, according to the March Equipment Market Data Subscription (EMDS) Book-to-Bill Report published today by SEMI.  A book-to-bill of 1.15 means that $115 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 March 2016 was $1.38 billion. The bookings figure is 9.4 percent higher than the final February 2016 level of $1.26 billion, and is 0.9 percent lower than the March 2015 order level of $1.39 billion.

The three-month average of worldwide billings in March 2016 was $1.20 billion. The billings figure is 0.5 percent lower than the final February 2016 level of $1.20 billion, and is 5.3 percent lower than the March 2015 billings level of $1.27 billion.

“Order activity remains steady and is on par with both the previous quarter and one year ago,” said Denny McGuirk, president and CEO of SEMI. “3D NAND and advanced logic are the key drivers for 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
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

$1,221.2

$1,310.9

1.07
February 2016 (final)

$1,204.4

$1,262.0

1.05
March 2016 (prelim)

$1,198.5

$1,380.5

1.15

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

By Rania Georgoutsakou, director of Public Policy for Europe, SEMI

In a global industry, monitoring regulatory developments across different regions can be a challenge. Add to that the additional complexity of communicating with a (global) supply chain, then consider that each company has to individually reach out to its suppliers and customers. This results in numerous communications on the same issue up and down the supply chain, and the benefits of industry collaboration within associations such as SEMI become clear.

To help companies keep up with the latest developments in the EU, here’s a list of recent and upcoming regulatory initiatives and how SEMI member companies are collectively addressing these:

  • SEMI FAQ – EU F-Gas regulation and semiconductor manufacturing equipment
  • Review of EU Machinery Directive now underway
  • EU PFOA restriction under discussion
  • 2016 EU Blue Guide is available

A SEMI webcast on EU regulatory developments (March 2016) provided a more detailed overview of these and other developments and how companies should prepare – the webcast is available to view for SEMI member companies only, please click here and select the “EU Regulation Webcast”.

Manufacturing equipment containing pre-charged chillers – new SEMI FAQ provides guidance on how to comply with EU F-Gas law

The EU F-Gas regulation that entered into force in January 2014 creates new restrictions on placing on the EU market pre-charged chillers containing certain fluorinated gases (F-gases).

A new SEMI FAQ on the EU F-Gas regulation provides guidance on what this law is about, how it impacts semiconductor manufacturing equipment and what steps companies importing affected equipment should be taking to ensure compliance.

If your company is importing semiconductor manufacturing equipment containing pre-charged chillers into the EU, then you need to make sure you can account for the f-gases in the chiller under the new F-Gas quota system that the law has established, by obtaining an ‘authorisation’ from a ‘quota holder’ and registering in the ‘EU HFC Register’.

For more details and compliance timelines, check out the SEMI FAQ.

EU Machinery Directive – review now underway – have your say!

The EU Machinery Directive sets out the basic requirements machines must satisfy in order to be placed on the EU market and is a major piece of EU law for semiconductor manufacturing equipment.

The review is part of the regular EU regulatory review process to ensure legislation is ‘fit for purpose’ and does not automatically imply that the Machinery Directive will be revised. It is being run by an external consultant and a final report is expected in April 2017.

The focus of the review will be on 9 product categories, including machines for metal working, engines and turbines, robotics and automation and will also explore whether there are discrepancies in the interpretation of the directive between various member states and to what extent it is aligned to other pieces of legislation.

SEMI is putting together a working group to contribute to review of the EU Machinery Directive. If you are a member company and want to get involved, please contact [email protected]

PFOA restriction under discussion – SEMI requests derogations for the industry

The EU is currently drafting a law to restrict the manufacture, use and placing on the market of PFOA, its salts and PFOA-related substances under EU REACH. The restriction would apply both to substances and mixtures and to articles containing these substances.

SEMI has been calling for a derogation for substances and mixtures used in photolithography processes and for articles contained in semiconductor manufacturing equipment.

SEMI has collected and submitted evidence to substantiate members’ recommendations for:

  • a derogation period of at least 10 years for semiconductor manufacturing equipment, to allow equipment manufacturers to communicate with their the supply chain, identify components potentially containing restricted substances, source substitute parts that are tested and validated and requalify the equipment.
  • non-time-limited derogation for spare parts for legacy semiconductor manufacturing equipment, i.e. equipment that was already on the EU market before the restriction entered into force and before the derogation for semiconductor manufacturing equipment expires.
  • non-time-limited derogation for second-hand semiconductor manufacturing equipment, to ensure that companies can still import used equipment from outside the EU or from another EU member state.

SEMI has also voiced its concerns around the proposed concentration limits and the non-availability today of standardized practicable analytical methods that can be applied to a variety of materials to test whether an article would comply with the restriction.

The EU proposed restriction will be published in the next month and the final decision on the restriction is expected by the end of 2016.

Product regulatory compliance in the EU – 2016 Blue Guide now published

The Blue Guide provides guidance on how to implement EU product rules, including for example the EU Machinery and EMC Directives. A 2016 revised version is now available to download – click here.

The Blue Guide addresses:

  • what constitutes placing a product on the EU market
  • obligations of the various actors in the supply chain (manufacturer, importer, authorized representative etc.)
  • product requirements
  • conformity assessment
  • accreditation
  • market surveillance carried out in the EU

For an overview of SEMI’s advocacy work in Europe, please click here.

To find out more and get involved, please contact [email protected]

Join us for the 10th SEMI Brussels Forum – the industry’s major annual event bringing together company executives and decision-makers to discuss opportunities for the micro/nano-electronics industry in Europe: www.semi.org/BrusselsForum

Invensas Corporation, a wholly owned subsidiary of Tessera Technologies, Inc. (Nasdaq: TSRA), announced today that Sandia National Laboratories signed a new license agreement for ZiBond and Direct Bond Interconnect (DBI) technologies. With this license Sandia will have access to the most advanced 3D integration technologies available, for use in a wide range of semiconductor applications.

For more than 60 years, Sandia National Laboratories has been the premier science and engineering laboratory in the United States for national security and innovation. Working closely with U.S. government agencies, private industry and academic institutions, Sandia has led the charge to research, develop and deliver essential technologies used to solve many of the nation’s most important security, climate change and sustainable energy challenges.

“The demand for cost-effective, versatile, 2.5D and 3D integration technologies has risen significantly, as research and commercial enterprises seek to expand overall performance and functionality of electronics products,” said Craig Mitchell, President Invensas Corporation. “ZiBond and DBI technologies are currently deployed in leading edge semiconductor products, and we are pleased to now make them available to Sandia, a premier government research institution.”

ZiBond is a low-temperature homogeneous bonding technology, that enables room temperature die or wafer-level 3D integration, without the need for the application of external pressure. DBI is a low temperature, hybrid bonding technology with integrated electrical interconnects, that offers the industry’s finest pitch and lowest cost-of-ownership 3D interconnect platform.

Both ZiBond and DBI deliver the fastest bonding throughput currently available in the industry, resulting in up to a 15x increase in wafer bonding throughput. Both technologies offer the thinnest available 2.5D and 3D semiconductor assemblies, while reducing wafer warpage, increasing reliability and improving thermal performance. Additionally, low processing temperatures significantly reduce equipment and process cost for high volume manufacturing.

For more information on ZiBond and DBI technologies as well as other Invensas solutions, please visit www.invensas.com or www.tessera.com.

To overcome the current market and technology constraints taking place today within the semiconductor industry, new advanced packaging technologies have been developed by industrial companies. Leaders in the advanced packaging industry have identified new solutions enabling more and more functionalities to be integrated along with many devices in the same package. Yole Développement analysts are currently noting plenty of excitement within the advanced packaging sector: research, innovation and industrialization are the key words of the current industry status.
In this context, NCAP China (NCAP) and Yole Développement (Yole) are pursuing their collaboration and have announced the second Advanced Packaging & System Integration Technology Symposium:
• The symposium will take place in Wuxi, China, on April 21 & 22.
• Click program & registration to see the schedule, list of speakers, abstracts, and more.

In 2014, the first symposium was a notable success: in addition to attracting more than 80 attendees, the show generated numerous valuable discussions, meetings and business collaborations. In 2016, NCAP and Yole are excited to welcome the leaders of the advanced packaging industry for the second time, and are expecting a similar success. They have announced an impressive list of executive speakers including:
•  Li Ming, R&D Director, ASM Pacific technology
•  Ruurd Boomsma, Sr. VP Die Attach & CTO Besi Die Attach & Besi Group
•  Farhang Yazdani, President & CEO, BroadPak Corporation
•  Herb He Huang, Ph.D., Sr. Director, 3DIC & Sensors Technology Development, Corporate R&D Center, Semiconductor Manufacturing International Corporation (SMIC)
•  And many more: the lists of speakers, biographies, and abstracts are available on the i-micronews website. To download the PDF version, click Program & Abstracts.

The collaboration between NCAP & Yole is based on strategic thinking from both organizations. Both names and their international reputation send a strong signal to the advanced packaging community.

NCAP is a technology development center. Its aim is to build up leading edges in advanced packaging by IP licensing and commercialization of technology development and transformation, with a smart combination of the packaging supply chain constraints. This organization has, of course, an important role to play at the national level by developing and supporting valuable advanced packaging expertise and capabilities with local industrial partners.

“The whole advanced packaging industry is facing unbalanced development of semiconductor equipment and materials,” explained Dr. Cao LiQiang, CEO of NCAP. “Prices and cost monitoring are crucial to ensuring the sustainability of the companies.”

For its part, as a “More than Moore” market research and strategy consulting company, Yole is pursuing its research within the advanced packaging world and is expanding its expertise and understanding of this industry, day after day. The number of technology and market reports available each year and dedicated custom collaborations with multiple companies throughout the advanced packaging supply chain show the leadership of the consulting company within this sector.

“At Yole, we expect solid advanced packaging market growth reaching US$30 billion by 2020,” explained Thibault Buisson, Business Unit Manager, Advanced Packaging & Semiconductor Manufacturing at Yole (Source: Status of the Advanced Packaging Industry 2015 report, Yole Développement, November 2015). And he added: “We currently see substantial activity in the Advanced Packaging ecosystem: many companies from different business models are getting involved in this area and the competition is intensifying, New innovative platforms such as System-in-Package, Fan-Out packages and 2.5D/3D technology are changing the industry landscape and turning a new page in Advanced Packaging evolution. This is the motivation behind the organization of the Advanced Packaging & System Integration Symposium. The symposium emphasizes the value transition in packaging and is aimed at providing answers to the current challenges and key questions that the industry is facing today.”

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“The Advanced Packaging & System Integration Technology Symposium taking place next week in China is the result of Yole & NCAP powerful collaboration, a combination of both technical know-how and market expertise,” said Jean-Christophe Eloy, President & CEO, Yole Développement. He adds, “It clearly represents a wonderful opportunity for advanced packaging companies to develop, exchange and expand their activities to the advanced packaging industry in China and also in all other countries.”

NCAP and Yole are extremely enthusiastic about the 2nd advanced packaging symposium. Both partners welcome all industry leaders including: Alpha Szenszor, ASE Group, ASM Pacific Technology, Besi, BroadPak, Evatec, EV Group, JCAP, HuaTian Technology, Huawei, Plasma-Therm, Sinyang, SPTS/Orbotech, STATS ChipPAC, Zeta Instruments, and more. To see the full schedule, please click here: Program.

Moreover, on the afternoon, and on a volunteer basis, NCAP will invite the participants to visit its facilites. Program includes NCAP Introduction, Material Consortium Plan Introduction, Lab Tour.
For more information about the schedule and registration, please contact: Clotilde Fabre ([email protected]), Communication Coordinator, at Yole Développement.

Molex, a global manufacturer of electronic solutions, announced today the acquisition of Interconnect Systems, Inc. (“ISI”) which specializes in the design and manufacture of high density silicon packaging with advanced interconnect technologies.

According to Tim Ruff, senior vice president, Molex, the acquisition enables Molex to offer a wider range of fully integrated solutions to customers worldwide. “We are excited about the unique capabilities and technologies the ISI team brings to Molex. ISI’s proven expertise in high-density chip packaging strengthens our platform for growth in existing markets and opens doors to new opportunities.”

Headquartered in Camarillo, California, ISI delivers advanced packaging and interconnect solutions to top-tier OEMs in a wide range of industries and technology markets, including aerospace & defense, industrial, data storage and networking, telecom, and high performance computing. ISI uses a multi-discipline customized approach to improve solution performance, reduce package size, and expedite time-to-market for customers.

“We are thrilled to join forces with Molex. By combining respective strengths and leveraging their global manufacturing footprint, we can more efficiently and effectively provide customers with advanced technology platforms and top-notch support services, while scaling up to higher volume production,” said Bill Miller, president, ISI.

Alpha and Omega Semiconductor Limited (AOS) (Nasdaq:AOSL), a designer, developer and global supplier of a broad range of power semiconductors and power ICs, today announced that it has executed a definitive agreement with two strategic investment funds owned by the Municipality of Chongqing, China, to form the previously announced joint venture for a new state-of-the-art power semiconductor packaging/testing and wafer fabrication facility in the Liangjiang New Area of Chongqing.

The initial capitalization of the Joint Venture under the agreement will be $330 million. This reflects cash contributions, primarily from the Chongqing funds, as well as existing packaging and testing equipment from AOS, and certain AOS intellectual property relating to packaging and wafer manufacturing technology. AOS will own 51%, and the Chongqing funds will own 49%, of the equity interest in the Joint Venture. The Joint Venture agreement is subject to approval by the relevant Chinese authorities.

“We are excited to begin this partnership, which we believe will enable both AOS and Chongqing to grow and prosper,” said Dr. Mike Chang, chairman and CEO of AOS. “This joint venture with Chongqing represents an important milestone in our strategic roadmap. It will help further diversify our offerings of power semiconductor products and improve our access to customers in China as we work to accelerate our long-term growth and profitability.”

The Joint Venture is expected to commence its initial packaging production in mid 2017. Prior to that, AOS intends to gradually relocate a majority of its assembly and testing equipment to the Joint Venture from its existing facility in Shanghai, which will continue as a center of supply chain management, technology development, and high-value production. Over the longer term, the Joint Venture expects to construct a 12-inch wafer fabrication facility for the production of power semiconductors.

The Joint Venture is designed to bring together the technological and operational capability of AOS in power semiconductor product manufacturing with the capital resources and regional infrastructure support of the Chongqing authority.

Texas Instruments Incorporated (TI) announced that Devan Iyer has been elected vice president of the company. As vice president of worldwide semiconductor packaging, Iyer leads a global team responsible for determining the semiconductor packaging design and technologies that help customers differentiate their products and enable further cost-effective advancements in miniaturization and performance.

“Devan’s technical expertise and commitment to innovation are vital to TI’s growth as we deliver the next wave of advanced packaging solutions to meet customers’ needs,” said Kevin Ritchie, senior vice president of Technology and Manufacturing Group.

Iyer joined TI in 2008 in TI’s Technology and Manufacturing Group as a manager of semiconductor packaging. He most recently served as director of worldwide semiconductor packaging and has more than 22 years of semiconductor industry and R&D experience.

Iyer earned a bachelor’s degree in applied electronics from the University of Kerala in India, as well as a master’s degree in microelectronics from the Indian Institute of Technology Kharagpur in India and a doctoral degree in microelectronics from the Loughborough University of Technology in the United Kingdom.

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.

Screen Shot 2016-03-25 at 1.50.30 PM

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.

Screen Shot 2016-03-25 at 1.50.38 PM

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.

Screen Shot 2016-03-25 at 1.50.52 PM

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]