Japan

Atomic Layer Deposition (ALD) players are poised to seize a new growth opportunity after the chip shortage pushed manufacturers to announce fab capacity expansions worldwide. Driven by the wafer production volume increase, ALD solutions are now expected to grow and enter the MtM devices market.

As part of bi-weekly meetings of the SEMI Environment, Health, Safety and Sustainability (EHSS) community to share information on the impacts of the pandemic, the EHSS COVID-19 Working Group recently revealed that companies are offering PTO to employees to get vaccinated.

As we move through Q2 of 2021, it seems that the world is finally approaching normalcy. But I don’t believe our lives and businesses will ever be the same. Travel is unlikely to return to the same level as pre-COVID-19 for many years. I’m sure many companies will establish tighter travel policies and budgets as virtual conferencing has proven to be beneficial and cost-effective. Patients and doctors who were skeptical of telemedicine are embracing it, and although it’s not perfect, it has filled a needed gap. Online learning essentially happened over a weekend and will now be part of many curriculums and programs. All of these elements have spurred our semiconductor industry into a super cycle. Demand for chips is leading to an increased demand for semiconductor equipment. Semiconductor capital equipment expenditures in 2020 surpassed $63 billion and are forecast to top $70 billion in 2021. The secondary equipment market typically makes up about 5% to 10% of that. Our inquiries have definitely increased this year. With this in mind, I’d like to share some thoughts for the remainder of the year. Storage of Chipmaking Equipment Not New The semiconductor industry has been experiencing an equipment shortage for some time. It is difficult for original equipment manufacturers (OEMs) to support such a large variety of products and technologies. Some companies use equipment for manufacturing 150mm, 200mm and 300mm wafers. Fabs still run 30-year-old technology on 150mm wafers while the latest technology is manufactured on 300mm wafers. We’ve also seen new technologies like silicon carbide (SiC) being developed on these smaller wafer sizes. Unfortunately, some OEMs stopped making 150mm and 200mm some time ago and have only recently jumped back into the market. These OEMs have had to balance technological advances, pricing, and manufacturing capacity to meet this demand since their primary focus is on 300mm equipment. Third-party refurbished equipment suppliers have also experienced an increase in demand over the last several years. We see it increasing at all technology levels over the next three to five years. This translates to increased equipment pricing for both new and used equipment, as well as increased lead times. Growing Demand for Legacy Tools Many electronic products we use and are familiar with don't require state-of-the-art technology. For instance, cellphones, electric vehicles, wearables, monitors and industrial products still contain many chips manufactured on 200mm wafers using 200mm equipment. There are still approximately 200 200mm fabs worldwide and this makes up about 25% of all wafer capacity regardless of wafer size. These fabs manufacture analog devices, MEMS products, power management ICs, RF devices, discrete devices and sensors. We have also seen an increase in lead times for 200mm equipment. Typical lead times of three to six months have increased in some cases to one year or more. This situation has created a dramatic increase in chip making equipment prices and we do not expect much relief there. Many OEMs transitioned to 300mm equipment prior to 2010. Revenue and profit margins are much higher for them on 300mm equipment. 200mm manufacturing was supported by many third parties for a while. However, in 2016 we saw a resurgence in 200mm equipment, and at that time many OEMs began jump-starting their supply chains. It took some time for them to develop new supply chains, upgrade technology and in some cases hire newly trained engineers to support these new tool sets. All this costs money, which is why we will continue to see an increase in new legacy equipment pricing. Because manufacturers and products may not be able to support these prices, we expect the robust third-party ecosystem to continue. SurplusGLOBAL's Response to this Demand One of the advantages we bring to the secondary equipment market is our ability to recycle technology. We continuously search for opportunities to purchase large packages of tools from companies that are transitioning technology nodes, moving from 200mm to 300mm wafer size or changing product lines. We spend approximately $65 million to $100 million each year on purchasing equipment and in some cases storing it for the right customer. For instance, a memory company may be changing technology nodes and no longer needs its equipment. This use to happen on a predictable schedule. Instead of scrapping that equipment, SurplusGLOBAL purchases and stores it. Sometimes we only need to store it for one month before relocating it. However, in many cases, we store it for one year or more. We may power it on at a later date if it is in good condition. In some cases, we work with an OEM or third party to have it refurbished and ready for a new customer. In response to the need for more secondary market equipment, we have opened up additional offices in Japan and Singapore to stay close to and better support our customers in those regions. Finally, our biggest and most recent endeavor is building our Semiconductor Equipment Cluster, which opens in July 2021. Learn more about the SurplusGLOBAL Semiconductor Equipment Cluster. Emerald Greig is executive vice president Americas at SurplusGLOBAL.

If you look at your clothes or shoes, there is a growing chance you will see the words Made in Vietnam printed on the tag. Since the United States lifted its trade embargo against Vietnam in 1994, the country has become the second largest exporter of apparel and shoes to the U.S. What may be less evident is the source of that new electronic gadget you received for Christmas, with its numerous parts, chips, and intricate supply chain. While light manufacturing has dominated Vietnam’s economic growth since the Đổi Mới economic reforms implemented in the 1980s, over the last decade the country has been repositioning itself to become a dominant player in the global microelectronics industry, a trend that has gained momentum in the wake of the U.S.-China trade war. In 2019, Vietnam ranked as the fourth largest exporter of electrical goods and components to the U.S. With exports doubling over the last four years and now exceeding $19 billion, surpassing Taiwan, Japan, and Korea (based on goods exported under chapter 85 of the Harmonized Tariff Schedule). Vietnam’s global electronics industry now accounts for about 40% of its exports, and the country seems to be just getting started. Early Entrants Though Vietnam owes its growing success in attracting foreign direct investment (FDI) in the semiconductor and microelectronics industries to the advent of China plus one – the business strategy to diversify business investments geographically – it was the few early entrants that gambled on this emerging market a decade ago that put Vietnam on the global stage. Of these early players, no other firm comes close to having the impact that Samsung has. It’s initial $670 million mobile phone manufacturing plant in the northern province of Bac Ninh in 2008 grew to a country-wide investment of $17.3 billion within a decade. Samsung is now Vietnam’s largest FDI contributor and accounts for more than 25 percent of its exports. Because of Samsung, Vietnam has become the second largest exporter of smartphones in the world. Around the same time, Intel opened its $1 billion semiconductor assembly and testing facility in Ho Chi Minh City, putting Vietnam firmly on the global technology map. More investors, like LG, Panasonic and Foxconn soon followed. Within a few years of these initial investments the industry was taking notice, illustrated by SEMI’s role in co-organizing the Vietnam Semiconductor Strategy Summits in 2013 and 2014. With SEMI SEA’s increased efforts to promote Vietnam as an important ecosystem in the electronics supply chain, more will be done to positively influence the growth and prosperity of its member companies in Vietnam. These early investors found Vietnam attractive for several reasons. Key among these are the country’s low wage rates combined with its favorable demographic structure – what the UN refers to as the golden population structure, which provides “Vietnam with a unique socio-economic development opportunity.” Companies are also attracted to the growing number of Free Trade Agreements (FTAs) that Vietnam belongs to, including the ASEAN Free Trade Area, CPTPP, the EU-Vietnam FTA, and, most recently, RCEP. Though the U.S. has yet to ink a trade agreement, the Singapore AmCham’s annual regional survey has consistently identified Vietnam as the most attractive country in ASEAN for a potential bilateral FTA partner with the U.S. Leveraging the Trade War If the plus one strategy was the catalyst that started this wave of electronics manufacturing in Vietnam, then the U.S.-China trade war was the enzyme that supercharged it. A common quip in Southeast Asia is that the U.S.-China trade war is over and Vietnam is the winner, and this is apparent in both trade and investment trends. According to the Asia Development Bank (ADB), the riff between the U.S. and China has caused a redirection in trade, as U.S. imports from the PRC fell by 12% in the first six months of 2019 while U.S. imports from Vietnam increased by 33%, with electronics and machinery accounting for the bulk of this jump. The ADB further reported that in a prolonged and intensified trade conflict, the worse-case scenario would result in Vietnam, Malaysia, and Thailand being the biggest winners, “in that order.” On the investment side, a March 2020 Gartner, Inc. survey of global supply chain leaders revealed that 33% had “moved sourcing and manufacturing activities out of China or plan to do so in the next two to three years.” While this survey did not mention specific winners, the ADB reported that “newly registered FDI in Vietnam from the PRC and Hong Kong rose by 200% year on year in the first seven months of 2019,” indicating the move of Chinese suppliers to Vietnam. Additionally, a review of recent press reports indicate firms like Apple, Nintendo and Dell are encouraging suppliers to move parts of their supply chains to Vietnam. These suppliers are complying, with Compal Electronics, GoerTek, HZO, Inventec, Luxshare Precision Industry, Pegatron, USI and Wistron all reportedly announcing plans for new investments in Vietnam. Manufacturing Hubs Within Vietnam, microelectronic facilities have concentrated in a few geographic hubs. In the south, the Saigon High Tech Park in Ho Chi Minh City attracted early entrants Intel and Samsung, with firms like Nidec and Jabil soon following. The largest investment capital, however, developed in the northern provinces that ring Hanoi. Bắc Ninh, an hour’s drive from Hanoi, was the site of Samsung’s first investment and has since attracted Foxconn and Canon. More recently, firms have been drawn to the port city of Hải Phòng, the country’s third largest city, which is already home to Samsung and LG. The city’s close proximity to other manufacturing clusters, its new deep-water port, and its expressway that provides a 12-hour trucking route to China’s electronics epicenter in Shenzhen are helping make the city Vietnam’s new high-tech production center. In 2019, LG Electronics moved its entire smartphone production line from South Korea to Hải Phòng, and in 2020 Pegatron reportedly chose the city for its $1 billion investment plan. Local phone manufacturer VinSmart is also producing the country’s first 5G smartphones in Hải Phòng. In November, USI, a subsidiary of Taiwan-based ASE Holding, broke ground on its first production base in Southeast Asia, a $200 million phase-one investment in the production and assembly of chips for wearable electronic devices. USI’s investment, which is moving into the internationally managed DEEP C Industrial Zones in Hải Phòng, is “intended to move us closer to our overseas customers and accommodate their ever-increasing demand,” according to Mr. Kuei Chun Chi, the firm’s Manufacturing Service Director. “North Vietnam, with its strategic geographical position and an extended infrastructure in place, offers USI an optimal way to facilitate fast and flexible response to customers' orders.” Though the Covid-19 pandemic has dampened the pace of new investments in Vietnam’s microelectronics industry, it has also amplified the country’s attractiveness to investors. Vietnam was successful in containing the outbreak through aggressive quarantine and contact tracing measures, and as a result its economy has the brightest outlook in the region. The ADB forecasts the country will be one of the fastest-growing economies in SEA in 2021, with GDP estimated at 6.8%. The Ministry of Industry and Trade is also reporting that several of the world's largest technology corporations plan to shift their production chains to Vietnam post-Covid-19, an indication that technology firms will accelerate relocation plans in 2021. Vietnam’s successful response to the pandemic, combined with its strategic location, low wage rates and foreign trade agreements, will ensure that the region continues to benefit from the shift in supply chains in Asia, making it the new destination for electronics manufacturing. About the Author Stuart Schaag is Principal at E-Ward Trade Consulting LLC, which assists firms that are expanding their presence in the global marketplace by creating strategies combining market analysis, business development, commercial diplomacy, and relationship building. He previously spent 25 years in various domestic and overseas positions in the U.S. Department of Commerce’s International Trade Administration. Stuart served as the Commercial Counselor at the U.S. Embassy in Hanoi from 2014-2018 and resided in Vietnam until 2020.

The SEMI Smart Manufacturing Americas Chapter, a key driver of the Global Smart Manufacturing Initiative, accelerates awareness of digital and data-driven strategies and implementations to help speed adoption of smart manufacturing. In 2021, the Chapter will focus on expanding its work across the industry to include academic and research initiatives. The semiconductor industry saw an unprecedented focus on improving digital monitoring of manufacturing activity in 2020, partially due to COVID-19. The Americas Chapter shared case studies on new tools and techniques for social distancing in fabs, aides for remote maintenance, and tips for remote workers. The Chapter also introduced its three pillars of Sensing, Connecting and Predicting and offered related programs. The Global Smart Manufacturing Conference (GSMC) highlighted the significance of universities and research institutions in the development of smart manufacturing with their focus on joint research for broad dissemination. To help drive smart manufacturing advances, at GSMC several offered non-proprietary tutorials on topic including the following: Integrating sensors for acquisition – CEA-Leti Applying new AI and ML tools and strategies to manufacturing – Binghamton University Digital tools for planning, qualifying and management and scheduling in fabs – MINES Saint-Étienne. Adding AI tools to robot work in a smart factory – KAIST Institutes By continuously highlighting the activities of these and other institutions through presentations, interviews, articles and blog posts, we will draw more attention to what is on the horizon for smart manufacturing in 2021. The SEMI Smart Manufacturing Americas Chapter also plans to elevate activities important to the Outsourced Semiconductor Assembly and Test (OSAT), Surface-Mount Technology (SMT) and Printed Circuit Board Assembly (PCBA) segments of the industry including programs on inspection, traceability and the SEMI SMT-ELS Standard for SMT automation. Thurston Taylor, marketing expert at Tokyo Electron and Vice Chair of the Americas Chapter, notes that “With increasingly more demanding requirements for bump, assembly and test, smart manufacturing and applied data science are necessary to achieve back-end goals now and in the future.” Also, many companies are implementing smart manufacturing applications and assessing various strategies to increase their smart manufacturing capabilities. Members of the Americas Chapter plan to review and develop self-assessment documents and maturity models that apply to front-end wafer fabs all the way through packaging and assembly facilities. “Moving forward it is imperative for all of us to up the intensity on specific ROI vectors such as quality, cost, productivity, sustainability and safety leveraging our smart manufacturing SEMI framework of Sensing, Connecting and Predicting,” said noted Bobby Mitra, worldwide director of Smart Manufacturing at Texas Instruments and Americas Chapter Chair. “By offering special flagship events, invited talks, ROI case-studies and ROI criteria in maturity models, we’ll bring high value to the smart manufacturing industry.” Chapter members also will begin mapping the skills needed to implement and support increasingly digital manufacturing capabilities, including any new skill sets, to help companies develop their hiring, training and management strategies. The mapping effort aims to support companies in building a strong pipeline of employees who can efficiently manage and operate smart manufacturing facilities. For its part, the Americas Chapter’s Go Green Subcommittee will focus on applying smart manufacturing technology to reducing the electronic industry’s carbon footprint by accurately tracking energy waste improving overall fab efficiency. Stay tuned for details on activities planned for our chapters in Europe, China, Japan, Korea, Southeast Asia and Taiwan. To learn more about each chapter and how to get involved, please visit the SEMI Smart Manufacturing Hub and sign up for our newsletter. Ayo Kajopaiye is senior project coordinator, Collaborative Technology Platforms, at SEMI.

In my role as lead for the Smart Mobility initiative at SEMI, I recently spoke with Automotive Logistics Magazine about the growing importance of the semiconductor supply chain’s connection with the automotive industry and the semiconductor shortage hampering global automotive production. Following are excerpts from the interview. Automotive Logistics: Why is there a bottleneck in the global supply of semiconductors at the moment and how long is it likely to last? Weiss: The current automotive chip shortage resulted from the sharp, Covid-19-induced decrease in demand for automotive semiconductors in the second quarter of last year when vehicle production came to a near standstill. The automotive market picked up significantly in the fourth quarter and this caused the supply chain constraints we are seeing today. At the same time as the automotive standstill, the pandemic spurred an increase in demand for home computing and networking equipment, and semiconductor manufacturing plants (fabs) had to pivot to these other markets in order to maximize fab utilization and successfully navigate economic headwinds. Every minute a semiconductor fab is idle or has lines down adds up quickly to missed revenue, so their capacity is booked weeks and even months in advance. With this background, I don’t believe this is a structural shortage and expect a gradual recovery over the next two quarters, barring any major shifts in geopolitics or macroeconomics. Automotive Logistics: What needs to be done to remedy the current shortfall for the automotive industry? Weiss: The automotive industry needs to continue to strengthen its connections to the semiconductor manufacturing supply chain. In past years, auto manufacturers used to rely mainly on their tier one suppliers to interface with the semiconductor supply chain. This has changed significantly. Not only are more chips being used in vehicles (roughly 10% of all devices produced globally end up in cars), but the strategic importance of the chips as enablers for ADAS [advanced driver-assistance systems], electrification, safety, connectivity and other consumer-driven features has increased considerably. With this dynamic in play, carmakers have recognized the value of interacting and collaborating more closely with the semiconductor supply chain. This provides vehicle OEMs with access to innovation, the ability to influence technology direction and pace, along with greater visibility into global supply chain developments. The SEMI Smart Mobility initiative is evidence of this transition, with the likes of Audi, BMW, Ford, Uber, Volkswagen and other vehicle OEMs, along with tier one suppliers such as Continental and Bosch, now actively involved in our automotive electronics and mobility activities to do exactly that – influence, partner, accelerate and guide the global electronics design and manufacturing supply chain that SEMI represents. Automotive Logistics: What percentage of semiconductors manufactured for use by US-based companies are for automotive applications and how has this grown in recent years? Weiss: A little over 10% of semiconductors produced worldwide are sold into the automotive segment, but this number is expected to grow at an accelerated pace in the next few years as electrification, connectivity and autonomous driving become more prevalent. Automotive Logistics: How is SEMI working to help the automotive industry get a clearer view of sub-component supply and better manage supply chain risk? Weiss: The SEMI Smart Mobility initiative is designed to engage automotive OEMs, tier ones, semiconductor device makers, design houses, and equipment and materials companies to drive alignment across the supply chain and address shared challenges collectively. To facilitate this engagement, we created the Global Automotive Advisory Council (GAAC), which has active chapters in Europe, US, China, Japan and Taiwan. The GAAC provides an open platform for creating solutions, fostering collaboration and partnering with other industry bodies to accelerate and harmonize industry efforts that benefit the entire ecosystem. Volkswagen and Audi are already SEMI members – both are founding members of the GAAC Europe chapter – and have become vocal champions and critical contributors to our efforts. When all stakeholders work together, I have no doubt that the future of automotive and mobility will continue to be bright. Interested in learning more about this topic? Read the full interview in Automotive Logistics Magazine, A Fab Future for the Automotive Sector. Please contact me at [email protected] for more information about SEMI’s Smart Mobility Initiative, the Global Automotive Advisory Council, and how SEMI can help your organization navigate electronics in the automotive industry to drive innovation in the mobility space. Bettina Weiss is Chief of Staff and Global Smart Mobility Lead at SEMI.

If you think the world is flooded with a mind-boggling volume of digital content, then you might be just a amazed to learn about the sheer wealth of information and business opportunities that will be uncovered at this year’s SEMICON Japan as the event goes full digital.To start, more than 160 companies will exhibit their semiconductor manufacturing gear and services on the virtual show floor of Japan’s premier event for the semiconductor manufacturing and design supply chain. Add to that over 80 presentations and panels that feature global industry executives, visionaries and experts offering insights into the latest microelectronics developments, trends and technologies, and it’s easy to see how SEMICON Japan 2020 Virtual is designed to help attendees grow their businesses and the industry drive the next wave of innovations that promise to address some of the world’s greatest challenges across healthcare, the environment, transportation and other industries.Best of all, it will all be available at your convenience from your office or home 24 hours a day, making it safe and easy for you and others from all over the world to attend. Following is what’s in store at SEMICON Japan 2020 Virtual to help lead you into the future.Leading Japanese Securities Analysts to Weigh in What’s Ahead for the Chip Equipment Sector in 2021 For the first time, SEMICON Japan will feature Bulls Bears as Japan’s’ five top securities analysts focus on the 2021 outlook for the global semiconductor equipment sector. The December 17th event will include discussions on the COVID-19 pandemic’s impact on the semiconductor industry, the continuing geopolitical tensions that are forcing the industry to reconfigure its supply chains, the fast-growing China market and cutting-edge applications that are powering industry growth. The perspectives from Japan’s investment community are sure to be compelling as the region supplies one-third of the global semiconductor industry’s chip manufacturing equipment.Moderated by Akira Minamikawa of OMDIA, the panel will include these experts:Three Visionaries to Explore the Digital TransformationPowered by semiconductors, the fourth industrial revolution is driving digitalization globally, remaking societies to bring more efficiencies and conveniences to our work and home lives and help more people prosper. But the flip side of those tremendous benefits is the risk that wealth will be concentrated in the hands of people in positions of power, companies and nations. Democratizing economic development remains a serious challenge worldwide.Addressing this pressing issue, the Opening Panel on December 11 will feature prominent visionaries from political, academic and industrial communities including the following:Sony’s Leading-Edge Electric Car and Nissan’s Driver Assistance System to Highlight Automotive InnovationsCars are becoming more like smartphones on wheels, rapidly filling with more and more semiconductor chips every year with electrification and electronic driver-assisted systems to key drivers of this growth. At the SMART Mobility 1 session on December 14, two pioneering companies – Sony and Nissan Motor – will focus on both areas of semiconductor innovation.Sony’s Vision-S concept car, exhibited at CES 2020, astonished many in the electronics ecosystem and the automotive industry. What is Sony’s vision behind the vehicle? Izumi Kawanishi, Senior Vice President, AI Robotics Business at Sony will share the latest on the initiative.Nissan, maker of the pioneering LEAF electric vehicle, is the first Japanese carmaker to equip a car – its new Skyline – with the ProPILOT 2.0 driver assistance system for hands-off highway driving. Nissan Executive Vice President Asako Hoshino will provide an update on the company’s driver assistance system strategy and plans.Quantum Computing Meets Chip Manufacturing for the First Time at SEMICON Japan In contrast with current computer systems that use bits (binary 0 or 1 state) for computing, quantum computers leverage quantum superposition (0 and 1 states exist at once) to quickly solve highly complex problems that might take traditional supercomputers hundreds or even thousands of years to tease out. American physicist Richard Feynman promoted quantum computer as early as 1982, but it wasn’t until nearly two decades later and long after his death that quantum bit circuits emerged for use in superconductive materials.With quantum circuits and devices requiring state-of-art semiconductor processing technology, The Era of Quantum session on December 15 at SEMICON Japan 2020 Virtual will discuss necessary advances in chip manufacturing technology to enable the next generation quantum computing. The session will be the first time SEMICON Japan connects the semiconductor manufacturing and quantum computing communities.The program will feature the following experts:Strategies for Sustainable Semiconductor Industry GrowthSemiconductors are giving rise to a hyper-connected world that is fueling demand for staggering volumes of chips, pressuring the electronics industry to uncover new ways to increase manufacturing efficiency while reducing power consumption in a bid to help combat climate change. The Grand Finale Panel composed of executives from Japan’s semiconductor supply chain and a supervising ministry will gather for the Grand Finale Panel on December 18 to discuss ways the industry can achieve sustainable growth through innovation with a focus on energy savings and an new process technologies such as extreme ultraviolet lithography (EUV), which promises to enable electronics devices that are more power powerful, cheaper and more energy-efficient.Panelists include the following:Register TodayThe SEMICON Japan 2020 Virtual All-In Pass provides online access to all 80 presentations and panels, which will be available on-demand for replay until January 15, 2021. What’s more, all eight keynote programs will feature English subtitles. For complete information of the exposition, programs and registration, visit the SEMICON Japan website.I look forward to seeing you virtually at the event!Jim Hamajima is president of SEMI Japan.

Semiconductor equipment spending is mounting a strong recovery on the strength of explosive chip demand for work-at-home and study-at-home electronics fueled by the COVID-19 pandemic. Despite the growth, the 2017-2018 memory boon that triggered a critical subsystems shortage is still fresh on the minds of equipment suppliers as they worry whether critical subsystem providers can keep pace with the rebounding chip industry while managing the fallout from the COVID-19 pandemic.Hideyuki Koishi, president of HORIBA STEC, Co., Ltd., a leading supplier of mass flow controllers (MFCs), one subsystem critical to semiconductor production, recently spoke with SEMI about the company’s response to the COVID-19 outbreak, the pandemic’s impact on the global supply chain and the company’s ability to meet the demand for MFCs. SEMI: What COVID-19 countermeasures has HORIBA STEC taken?Koishi: To ensure employee safety and security while maintaining a stable supply of products to our customers, we started to deploy company-wide countermeasures when the Japan government declared a nationwide state of emergency to curb COVID-19 infections on April 16.HORIBA STEC and the entire HORIBA group formed a global COVID-19 task force and centralized all local outbreak decision-making to drive a rapid and effective global response. We quickly implemented work-at-home practices for our office staff and provided a safe environment for our factory workers, who are essential to maintaining product supplies, by establishing social distancing protocols and restricting site visits to essential workers. We also distributed face masks to all employees and placed disinfectant dispensers near the door of every room so employees could wash their hands before entering.To help on-site employees follow our social distancing guidelines, we reduced seating at cafeterias and converted meeting rooms to offices to give employees ample work space. We also established invisible walls in manufacturing facilities with multiple collocated divisions to restrict workers to their assigned areas, a containment measure that helps with social distancing while minimizing the risk of an entire factory shutdown if a worker contracts the virus. SEMI: Have you experienced supply chain disruptions due to COVID-19 outbreak?Koishi: Even though our supply chain extends overseas and includes China, fortunately we have not experienced any significant disruptions thanks to the broad geographic distribution of our supply chain. In addition, because many of our critical components are sourced in Japan, pandemic-related impacts to our business have been limited.Long before the COVID-19 outbreak, we organized a community called Rakuraku-kai with our suppliers in Japan to build and maintain close relationships. Although the community name suggests it is exclusive to Kyoto-based suppliers, its reach is a nationwide. After the declaration of state of emergency in June, the supplier community gathered for an ad hoc meeting to exchange information and share perspectives on the COVID-19 crisis.SEMI: Did you have any pandemic protocols in place before the COVID-19 outbreak?Koishi: In 2014, HORIBA group launched Stained Glass, a project designed to increase workforce diversity at HORIBA group companies through initiatives such as placing more women in decision-making roles and encouraging working at home to help employees better balance job demands with their family lives. As part of Good Place, the project’s program to increase the work-at-home rate, HORIBA group deployed a web-based meeting system and encouraged workers to transition from physical to online meetings. Good Place has helped our IT team and workers smoothly implement our work-at-home practices.Working at home is a beneficial practice regardless of its effectiveness in curbing infections. Employees can reduce commute time, increasing their quality. And it’s much easier and more affordable for international participants to join meetings since they’re spared the time and cost of travel. This year HORIBA group also moved its three-day bi-annual global meeting online to make them safer and more economical. The meeting is attended by about 100 leaders of group companies and business units.SEMI: Do you have any concerns about meeting demand for mass flow controllers?Koishi: We doubled the capacity of our main mass flow controller factory in Kumamoto prefecture in 2018 and with more floor space available for further expansion, we see no major barriers to meeting the growing demand from international customers in 2021 and beyond. Nonetheless, we must sustain the best possible COVID-19 countermeasures to maintain production while ensuring the safety of our employees.SEMI: Are you make any social contributions to combat the virus?Koishi: Semiconductors are not only indispensable for the electronics behind remote work, education and healthcare but they also play a critical role in developing COVID-19 therapies and vaccines. Thus, at HORIBA STEC, we believe our most important contribution is to maintain steady a supply of our mass flow controllers and other key semiconductor equipment components.HORIBA group also participates in two important pandemic initiatives. The Open COVID-19 Declaration program calls on intellectual property owners to make their patent rights, utility model rights, design rights and copyrights freely available in the fight against COVID-19. The program’s sole purpose is to stop the spread of COVID-19. HORIBA is among the 20 founders1 of this initiative.In June, HORIBA joined a push by the National Institute of Advanced Industrial Science and Technology (AIST) to develop a simple and rapid COVID-19 antibody test chip system. We’re contributing our expertise in immunoassay analysis and clinical laboratory equipment to help develop the system. SEMI: What have you learned from the COVID-19 outbreak?Koishi: The COVID-19 crisis has posed unprecedented challenges. Everyone hopes to return to normal soon but in reality things will never be exactly the same as before the crisis.Japan might have lagged other countries in its use of IT to improve business efficiency, but as we deal with the new coronavirus, both companies and their employees have been tirelessly considering reforms to the way we work through digitalization. I believe it will be difficult for companies to survive in the new normal unless they can incorporate these types of changes into their operations.On the other hand, I've also been reminded of the importance of traditional, analog communication. While we conducted all of our hiring interviews online this year, face-to-face meetings are a much richer experience that gives the prospective employee and the hiring company a much better sense of each other. In addition, as a company we need to continue to improve our ability to supply products so we can overcome challenges like the pandemic. COVID-19 has taught us our change needs to be more robust. We also need to evolve our business continuity plan to extend well beyond countermeasures to natural disasters such as typhoons and earthquakes. What matters most is that we apply the lessons of COVID-19 to make our business more resilient.[1] Ajinomoto Co., Inc., Canon Inc., Chanel G.K., GenoConcierge Kyoto, Inc., Honda Motor Co., Ltd., Horiba, Ltd., Konica Minolta Inc., Kyoto University, LSI Medience Corporation, Mitsui Knoledge Industry Co., Ltd., NEC Solution Innovators, Ltd., Nikon Corporation, Nissan Motor Co., Ltd., Rohm Co., Ltd., SRL, Inc., Shimadzu Corporation, Teijin Limited., Toyota Motor Corporation, Tsubakimoto Chain Co., and Yahoo Japan Corporation.Yoichiro Ando is a marketing staff member at SEMI Japan.

Japan’s semiconductor industry has weathered the COVID-19 pandemic to post robust growth. Far from a temporary setback, COVID-19 will lead to enduring change in how we work and live. And just as automation has been a bulwark against the devastating business impacts of the virus outbreak, increasing digitization will lead to new efficiencies in our industry.These were some of the key takeaways from three SEMI Japan Members Day webinars in June and July that offered the latest updates on COVID-19 impacts to the semiconductor industry and restart strategies for SEMI members. More than 2,000 SEMI members across Japan’s islands attended the webinars featuring the following five speakers: Hideki Kanewaka, Marketing Director, Consulting Lead, Japan, Accenture Japan Ltd. Takayuki Komori, Manager, Marketing Engineering Dept, SUMCO Corporation Taketoshi Hamaguchi, Director, Manufacturing Industry, Microsoft Corporation Akira Minamikawa, Senior Consulting Director, OMDIA (Informa Intelligence LCC) Yuichi Koshiba, Managing Director Partner, Boston Consulting Group COVID-19 Impact on Japan Semiconductor Industry is ModestThe consensus view of the five speakers from various quarters of the industry – consultant, IT service provider, materials supplier, market analyst – was that the Japan semiconductor industry withstood the heavy blows COVID-19 dealt to other industries thanks to strong demand for chips. Shelter-in-place policies and lockdowns spawned by COVID-19 has accelerated the digital transformation rippling around the world as electronics sales have soared to support everything from remote work and education to healthcare and home entertainment including gaming.The rapid growth of cloud usage for video streaming, gaming and remote work is taxing communications network capacity and placing more bandwidth demands on servers, said Akira Minamikawa of OMDIA. According to a recent report by Nokia, communications network traffic has skyrocketed 300 percent for online meetings and 400 percent for gaming, bringing the networks closer to their capacity limits. Minamikawa sees server shipments increasing at 8 percent CAGR through 2024. For the broader chip market, he expects demand for notebooks, solid state and hard disk drives, and gaming to remain strong in 2020. He also predicts rapid 5G penetration for smartphones will boost semiconductor chip industry growth.Still, not all semiconductor segments are expanding, said Yuichi Koshiba of Boston Consulting Group. Chip shipments for end products in markets such as automotive, industrial equipment and aircrafts are on the decline. Slowing demand for chips that power automotive applications in particular could pare sales for some chip companies and distributors since the segment accounts for a high proportion of their overall revenue.State of the Semiconductor IndustryFrom SUMCO’s vantagepoint as a major silicon wafer supplier, the company’s Takayuki Komori sees a number of changes unfolding in the semiconductor industry: Smartphones are driving growing demand for process technology (smaller nodes) and 300mm wafers. Komori estimates the typical high-end smartphone sports 1,700 square millimeters of silicon. 300mm wafers account for 80 percent of that total while more than 50 percent of the devices use leading edge multi-patterning technologies. Smartphones will need more RF chips to support 5G’s high-speed communications and added frequency ranges. Substrates for RF switches and tuners have been shifting from gallium arsenide (GaAs) and other compound semiconductors to silicon. 5G smartphone penetration will accelerate as the cost of integrating CPUs and modem functions into a single chip sees a swift decline. While the sensitivity and resolution of CMOS image sensors have evolved to incorporate innovative backside illumination and stacking technologies, future advances will focus more on products for machine vision applications capable of sensing invisible light bands. Rising adoption of electric vehicles and robotics applications will drive growing demand for power semiconductors that control their motors such as IGBTs and MOSFETs as the production capacity for the devices expands and shifts to 300mm wafer lines. For memory fabs, Minamikawa said utilization remains high as a result of a spending slowdown by major chip manufacturers and will stay elevated even once additional capacity ramps to support robust demand. Foundry fab utilization also remains high despite the pandemic-driven cancellation of smartphone chip orders in March. Minamikawa also sees the utilization rate of micro rising with the surge in demand for notebooks, PCs and servers in the second half of 2020.Transition to New NormalAs people around the world start to settle into new ways of living and working, there’s a growing acceptance that the transformation will be long-lasting. And no area of people’s lives is changing more than their work. Boosted by government subsidies, many small and midsize companies in Japan have started to implement work-from-home policies, an area where major electronics and IT businesses had already instituted reforms, said Hideki Kanewaka of Accenture. A few examples: Nippon Telegraph and Telephone Corporation (NTT) announced that half of its employees will continue to work from home in the future. A five-year plan Toshiba launched in 2019 to allow all employees to work from home will likely accelerate. Hitachi plans to allow all employees to work from home starting in April 2021. dwango, a major internet-based entertainment company in Japan, announced it will allow in principle any employees to work remotely. In the critical area of remote sales, Kanewaka pointed to the importance of going beyond online business meetings, paperless transactions and virtual events to devise new ways to attract customers and close deals. Creating online communities and providing rich digital content are also important measures to consider, he said.Manufacturing's Digital TransformationTravel restrictions by most countries to curb the COVID-19 outbreak have also raised barriers to chip companies sending engineers overseas sites to service state-of-art equipment and provide other technical support. Microsoft’s remote assist system deployed by ASML is one tool semiconductor makers can use to overcome this challenge, said Taketoshi Hamaguchi of Microsoft.The system connects a remote equipment service expert with an onsite worker through the internet, allowing the technical expert to provide support through a goggle display with a camera worn by the worker. Guided by the expert, the worker can perform complex services. A Natural User Interface (NUI) helps give the factory worker a clear understanding of the often highly technical instructions.Using artificial intelligence (AI) to increase automation will also help reduce the reliance of semiconductor factories on onsite workers. For example, AI deep learning can be deployed to calibrate equipment autonomously and reduce downtime after scheduled maintenances, Hamaguchi said.Corporate Restart Strategies Beyond factory considerations tied to COVID-19, semiconductor companies will need to adapt their business strategies to new ways of operating. For example, global supply chains will shift to domestic sources and increase redundancy to ensure a steady supply, a change leading to higher overall costs, Koshiba said. Trade routes among regions will also be redrawn as the trade rift between the United States and China and other geopolitical tensions intensify. The total value of those routes is expected to recover by 2023.Koshiba advised companies to evaluate the supply chain trade-offs between stability and cost and factor in potential risks to improve their short-term resilience and drive mid- to long-term supply chain restructuring.After past recessions, 14 percent of companies restored sales growth, Koshiba said. He recommended investing aggressively in growth and seizing M A opportunities during the downturn. Chip companies must also adapt to supply chain changes faster than competitors.Become a SEMI MemberWebinars like the recent SEMI Japan Members Day series have become increasingly important in the mix of programs and services SEMI offers members to help them connect, collaborate and innovate in the microelectronics community. To become a SEMI member, please visit the SEMI website or contact your nearest SEMI office.Jim Hamajima is president of SEMI Japan.

Linx Consulting and Hilltop Economics continue to monitor how the global economy impacts the electronic materials supply chain. Amidst the recent economic and revenue results releases, we have generated a series of potential scenarios for the next few years. These scenarios are based around sales of silicon wafers expressed in millions of square inches (MSI). Our work develops a multiyear forecast from the historic record of the SEMI-reported MSI demand by developing an econometric relationship with underlying demand drivers. Using this methodology, Linx Consulting and Hilltop Economics have introduced the following three silicon demand forecast scenarios: V-shaped global recession consistent with severe COVID-19 impact followed by a sharp economic rebound. Probability of approximately 40%. V-shaped global recession but with business and consumer behavior differing from the past recession in that there is much more aggressive spending on technology goods that softens the impact for semiconductors in 2020. Probability of approximately 25%. An extended COVID-19 impact developing into a U- or L-shaped global recession with an economic rebound delayed for several years. Probability of approximately 35%. In the few months since coronavirus hit the world, the economic prognosis for all major economies has worsened dramatically, although forecasts remain speculative given the rapid rate of change in the political and economic environment. The forecast changes in GDP since February 2020 of the G7 nations vary from -5.9% for Japan to -10.2% for Italy. These changes are closely linked to unprecedented declines in employment, consumer demand and industrial investment – all key drivers for wafer area demand. This leads us to believe there will be a significant reduction in wafer demand as these economic factors feed through the supply chain.Other leading indicators show dramatic drops in the global and regional economies taking effect at an unprecedented pace. These indicators have a loose predictive relationship for silicon wafer consumption and portend a rapid drop in demand.The demand picture for the semiconductor supply chain (be it wafers, materials, consumables or devices) is thus gloomy, and our models are currently showing Q2 to Q3 2020 reductions in MSI demand of between -11% and -28% depending on the scenario.In marked contrast to this depressing economic picture, the indications from the end-to-end semiconductor supply chain continue to be much more positive. Demand for silicon reported by SEMI increased in Q1 2020 by close to 3% from Q4 2019, while results from materials supply companies vary from slightly negative to record-breaking growth rates through the first three to four months of 2020. Added to this, reported revenues from WSTS for Q1 2020 ticked up 6.2% versus the prior year and the three large foundries in Taiwan and China showed continued growth of Q1 wafer area shipments and a 32.3% growth versus Q1 2019.Revenue and demand reports from leading device manufacturers remain on trend from 2019 with no indication of a precipitous change. Anecdotal reports of strong technology equipment demand to support people working from home and demand for medical devices in response to the pandemic can be substantiated somewhat by demand data although not convincingly.Reports from materials supply companies indicate that factories continue to be fully utilized, having been designated essential businesses, and that safety measures implemented against infection are largely effective.There are some indications of caution, however. The major public silicon wafer suppliers saw a 4% drop in revenues in Q1 over Q4, despite the reported strength in silicon area shipments from SEMI, indicating either ASP declines or some inventory effects.We are advising clients supplying materials into the wafer fabs and packaging supply chains to develop contingency plans for a sharp decline in product demand of as much as 28%, which may bounce back rapidly to 2019 levels or higher in early 2021. However, companies should also be vigilant of a slower than hoped for return to previous activity levels if the effects of the pandemic continue for an extended period.For further information please contact Mark Thirsk at +1 774-245-0959 or on [email protected] in engaging with the electronic materials supply chain? The Electronic Materials Group (EMG) is a SEMI technology community representing SEMI member companies that provide substrates, polymers, metals, organic and inorganic materials, chemicals, and gases developed for electronics manufacturing. Linx Consulting is a longtime member and supporter of the SEMI Electronic Materials Group.Mark Thirsk is managing partner at Linx Consulting. Duncan Meldrum is president of Hilltop Economics.