semiconductors

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.

In 2020, the global semiconductor materials market expanded 5% to reach $55.3 billion in revenue to set a new industry record. The momentum in growth is expected to continue throughout 2021 despite the lingering pandemic.

Shari Liss, executive director of the SEMI Foundation, is determined to help more people discover careers in the microelectronics industry. As a woman and longtime leader in both education and tech, she has a keen understanding of how chip industry jobs are often not visible or accessible to many people. To address this, she is spearheading the SEMI Foundation’s Industry Image and Awareness Campaign. I asked Shari to tell me about herself, her passion for this work, and this important campaign.Williams: When did you join SEMI? What were you doing before? What is your background?Liss: I joined the SEMI Foundation as executive director in September of 2019. I came to SEMI from Ignited, where as CEO I recruited, trained, and placed more than 400 educators in summer fellowships at top companies for transformative professional development that grew the Bay Area’s STEM talent pool and workforce pipelines. I'm an educator, a math geek, a mom, a musician, and a passionate advocate for a stronger, more diverse workforce.Williams: What is the Industry Image and Awareness Campaign?Liss: The Industry Image and Awareness Campaign, which SEMI has been running for several years, aims to dramatically increase awareness of the huge breadth of careers in the microelectronics industry and build its talent pipeline. The current campaign includes national media exposure and education that highlights careers in the U.S. microelectronics industry. It has two main components: a PBS documentary about our industry that will reach up to 60 million households, and an interactive website that will walk visitors through STEM career pathways and provide resources that increase industry awareness and interest, particularly among women, veterans and people of color. Integrated with SEMI’s Global Workforce Development Initiative, the website will help connect prospective talent to job openings while also focusing on the industry’s long-term workforce needs. The platform will function as a seamless point of contact, supporting recruiting and retention for employers while also serving those in need of upskilling or reskilling. It will target current industry workers as well as prospective employees, including students, veterans, and workers in other occupations.The two components will be integrated, with video content from the documentary series embedded on the website to provide inspiring stories from people already working in the industry.Williams: Why is this campaign important? What problem is it trying to solve in our industry?Liss: Currently, SEMI member companies have tens of thousands of open positions. These can only be filled if we aggressively and purposely attack the talent gaps. When we talk with students, soldiers and other diverse communities, they have little awareness of the kind of work there is in microelectronics, the jobs that await them, and the industry itself. Our industry generally does not have the same name recognition or understanding as social media or software companies, and many potential workers don't know about us.Students understand what’s on their phones and tablets – Google, Amazon, Facebook, Twitter, LinkedIn, Instagram, TikTok – but they don’t know that microelectronics technology powers all of it! STEM talent is already tough to find. Our industry’s relative invisibility makes it even more difficult to find the workers we need. This campaign aims to enlighten and inspire a new generation of innovative workers to join the microelectronics industry. Williams: Why does the microelectronics industry need a more diverse talent pipeline?Liss: The workforce development challenges we face as an industry are layered. We all know that our industry – and our need for a skilled workforce – will continue to grow. We also know that women and people of color are widely underrepresented. They face systemic barriers that start in grade school and continue through each individual’s professional journey. This is not only a significant problem from a social justice and equity standpoint, but it also hampers our companies and our industry.A large body of research shows that more diverse companies are more innovative, productive, competitive, and profitable. They also have less absenteeism, better retention, and greater company and customer loyalty. Our industry cannot fully thrive without a diverse workforce. That’s why reversing this trend is a priority and will take significant investments and systemic changes throughout the entire workforce pipeline. If we do that, we’ll have more successful companies and a dramatically improved industry over the next decade.Williams: Who are our partners in this effort?Liss: We are working with Roadtrip Nation and CAEL, both affiliates of Strada Education.Roadtrip Nation is an Emmy Award-winning media and career guidance nonprofit, whose mission is to empower people to define their own roads in life. Each year, Roadtrip Nation selects socially relevant topics for its narrative-based storytelling projects. Content from these “roadtrips” is then disseminated across a wide range of education and media channels to inspire the next generation with a more inclusive view of the future of work. Roadtrip Nation is creating the video content and the PBS documentary series focuses on the microelectronics industry.The Council for Adult and Experiential Learning (CAEL) is a nonprofit that helps forge a clear, viable bridge between education and career success, providing solutions that promote sustainable and equitable economic growth. CAEL is creating our interactive online platform that will clarify career pathways and guide users in navigating the learning opportunities that connect them to industry jobs and enable upward mobility and access to leadership roles.Williams: How are we engaging our member companies in this work?Liss: Our members and their talent needs are at the core of this work and informing it every step of the way. We are ensuring that the campaign meets these needs as well as those of our university partners, students and workforce development peers in the industry. Through multiple discovery sessions, we are capturing our members’ ideas, hiring challenges, skill gaps and other insights. The campaign’s member-based steering committee is guiding the project.Williams: What kinds of companies and leadership have been involved so far?Liss: Participation has already been incredible, with 38 member companies having joined us for more than 15 hours of discovery sessions and brainstorming. A dozen member companies participate in the steering committee, which is currently defining career pathways and industry needs.Williams: What are the participating companies saying so far?Liss: The response has been amazing! It is truly an unprecedented collaboration. Participants have been effusive about the experience. Here are some of their observations:“It was such a valuable and meaningful discussion. I was so glad to see that so many people from this industry are on the same page – perception, challenge, target audience, action items.”“I enjoyed the sessions very much and the insights from all participants, it is a valuable and meaningful cause.”“These are complex challenges that our industry faces, but kudos to you and SEMI for delving into the big issues and formulating a way forward to raise visibility and elevate perception for the next generation of leadership!”“This project will turn out great in the end! I am amazed at the progress in just a few days.”“I’m excited to see where this project can lead our industry! Thank you for all your hard work and leadership.”“The sequence of events was well structured, organized and focused. I strongly believe that these will be of great benefit to the industry!”Williams: What is the end result we’re working toward?Liss: Through powerful storytelling, amazing networking opportunities, and targeted marketing and outreach tools, we will reach millions of potential employees and open their eyes to the terrific jobs and careers in our industry. The awareness campaign, the website, the videos and the documentary series are all tools that will also reach parents, teachers, school counselors, and industry influences, all while supporting our member companies in hiring.Williams: When can the industry expect to begin to see results of the campaign?Liss: The Roadtrip Nation documentary series will likely air in the first half of 2022, and we anticipate the CAEL website to be live by mid-2022.Williams: What’s the most interesting or powerful lesson you’ve learned so far?Liss: The most powerful thing that I’ve learned is that no matter the company, the leader, or the employee, they all agree on the critical importance of attracting and retaining talent to sustain innovation and industry growth. Because industry awareness and image is such a vital challenge, it’s creating a shared passion across companies and participants. It’s been exciting to see this alignment.Williams: Why are you such a champion of this? What does it mean to you personally?Liss: Throughout my career, I have sought opportunities to grow and scale my impact in STEM education. From being an educator, to an administrator, to running a California-based STEM education nonprofit supporting educators, and now in my work at SEMI, I have always looked for ways to reach more educators and students. As my career progressed, my roles shifted to not just education content, but how to align industry and education. I am passionate about providing students with learning environments that help them understand how the subject matter applies to the real world. When we connect abstract concepts to real-world applications, the lessons tend to be so much more tangible and accessible to kids. It inspires them to want to keep learning those subjects and makes it more likely that they will be excited about what they are studying.At SEMI, I love that I can help form partnerships between the industry and education providers to amplify these messages. I look forward to working with industry stakeholders to provide career opportunities for diverse populations, for soldiers, and for women returning to work.For more information about the Industry Image and Awareness Campaign, contact Shari at [email protected]. Michelle Williams is deputy director of the SEMI Foundation.

As the global economy is constantly transformed, the need for new skills has never been higher. The microelectronics industry is thoroughly affected by this urgent need. To develop a workforce fit for the future, it is crucial to invest not only in reskilling and upskilling, but also in skills anticipation and inclusivity. To tackle this need, the European microelectronics ecosystem has adopted many bottom-up initiatives and good practices supporting lifelong learning. Many companies collaborate with universities and training institutes to offer work-based training, and numerous events take place to support women participation in STEM and to attract more young talent to a microelectronics career. Despite these great efforts, further pooling of investments is necessary if Europe is to develop efficient lifelong learning programs. Creating strong skills partnerships is vital for sustainable upskilling and reskilling initiatives. According to the World Economic Forum (2021), greater private-public collaboration on large-scale upskilling and reskilling initiatives could boost global GDP by $6.5 trillion and lead to the creation of 5.3 million net new jobs by 2030. What is the Skills Partnership? Against this backdrop, SEMI Europe is launching the Skills Partnership for Microelectronics. The partnership brings together industrial and education partners from the microelectronics ecosystem to implement the Pact for Skills, an EU initiative which aims to boost upskilling and reskilling investments in key ecosystems for Europe’s competitiveness. Following the high-level roundtable with SEMI Europe’s Advisory Board, hosted by European Commissioners Thierry Breton and Nicolas Schmit, the microelectronics sector was selected in November 2020 as one of the key ecosystems for the first wave of implementation of the Pact, alongside automotive and aerospace/defense. Read more details about the October 2020 roundtable. 59 partners have already endorsed the Pact for Skills for Microelectronics. The Skills Partnership for Microelectronics aims to: Exchange good practices of upskilling and reskilling initiatives of the microelectronics industry Develop sustainable collaboration mechanisms that will monitor microelectronics skill needs, learning from the examples of the METIS blueprint project Promote the microelectronics sector as a career choice Boost the presence of women and other under-represented groups in the sector. The partners will have the opportunity to liaise not only with European, but also with national and regional authorities and clusters, so that a pan-European holistic approach to microelectronics skills development is achieved, and a significant flux of public and private investments on skills is mobilized. To launch this ambitious partnership, SEMI Europe held an initial workshop on March 17. Participants included representatives from the European Commission’s DG Connect, DG Employment and DG Grow, national and regional authorities, and over 70 industry and education partners. The workshop opened with representatives from the European Commission informing all stakeholders about the Pact for Skills initiative, as well as about EU skills-related funding opportunities. In the framework of the Pact for Skills, the Commission will support the ecosystems with a Networking Hub, a Knowledge Hub and a Guidance Resources Hub. These platforms will be available later in 2021 and will act as a one-stop-shop to support the partners and provide information on EU policies and funding opportunities. Other presentations went on to set the scene, presenting the main priorities of the partnership. Françoise Chombar, CEO of Melexis, highlighted the skills challenge experienced by the microelectronics industry. She emphasized the importance of lifelong learning and the danger of the gender disbalance in the sector and underlined the huge innovation potential and profitability that could be unleashed for Europe if the gender gap is successfully addressed. Moreover, the preliminary results of the METIS Microelectronics Skills Strategy were presented, to offer the basis for the partnership’s approach to skills anticipation. The partnership will establish working groups that will investigate the industry needs, leading to a better connection with the offer of education and training programs. Last but not least, the partnership aims to promote national and regional funding of upskilling and reskilling initiatives. In this regard, representatives from national and regional authorities and clusters participated in the meeting. The government of the Basque region had an active role, presenting the region’s priorities, incentives and main actions on promotion of lifelong learning initiatives. The next steps The meeting concluded with an overview of the next steps for the newly launched partnership. In the next workshop, the partners will align on the specific KPIs, as well as on the focus areas where they would like to engage (skills anticipation in semiconductor manufacturing, skills anticipation in semiconductor design, gender balance, etc.). In that framework, the executive board will be established, as well as the working groups that will lead the work of the partnership and set targeted objectives. If you want to take active part in the creation of this large-scale initiative, please fill in your details here. To learn more about the initiative, click here or contact [email protected]. Stefania Gavra is public affairs manager at SEMI Europe.

As we pass the work-from-home one-year mark, most of us still work remotely and will do so for the foreseeable future. As live trade shows and technical conferences were cancelled one after the other, virtual events became the norm. And, teleconferencing became a way of life. While possibly overstating our role, we have the semiconductor industry – from system design through manufacturing and system integration – to thank for a long history of achievement that made the transition to working remotely relatively seamless and straightforward. The shift, in some cases, took some time to sort out as we set up a workable home office, moved to video conferencing with intermittent connections and settled into a routine. Nonetheless, many of us became more productive and, in some cases, even too productive. Each spoke in the global electronic products hub contributed through creativity and innovation with a pinch of ingenuity and grit. Of course, we could have worked remotely 10 years ago, but not nearly as efficiently. Over the last 10 years, the economy moved to the cloud, producing new opportunities across the global market. Many of these opportunities were made possible by the electronic system supply chain and combination of semiconductor technology, electronic product innovation and people who figured how to leverage it with software platforms to tie it together. Zoom, one of our teleconferencing lifelines, is a good example, as are Netflix, our ongoing source of entertainment, and Roblox, a platform to build games. Facebook, Twitter, LinkedIn and the like sourced the news for us and kept us in touch. Amazon delivered our online purchases and GrubHub brought us our takeout dinners. All rely on cloud computing with thanks to the semiconductor industry. Another great example are data centers powered by semiconductors and the amount of data they processed last year. According to International Data Corporation (IDC), 64.2 zettabyte (ZB) of data was created or replicated due to the dramatic increase in the number of people working, learning and entertaining themselves from home. (Its revised model for global data creation and replication predicts the CAGR will grow to 23% over the 2020-2025 forecast period, a sure bet that the semiconductor industry will address ways to manage the growth, possibly through new AI chips.) Our connectivity is driven by smartphones optimized for low power and the performance of more complex chips. Over the last 10 years, design tools have been enhanced and new methodologies have been introduced to respond to the needs of the increasing complex chips for applications that demand high bandwidth, low latency and reduced power consumption and area. Manufacturing is retooling for higher automation under smart manufacturing initiatives and packaging is even more sophisticated with increasing integration and the 2.5D and 3D packaging rollouts. Let’s take stock of our success. The semiconductor industry has a storied tradition of breakthrough technology since its inception. The consumer electronic product craze started when the first PCs were rolled out in 1971, notes the Computer History Museum. Primitive laptops that followed in 1986 gave way to notebooks in 2007 and the ubiquitous smartphone in 2002 – and the rocket fuel for much of this was the buildout of computer networks, hyperscale datacenters and the cloud. Nothing’s been the same since. The next time we turn on our laptop, click on the link for the latest teleconference from our remote home office in comfortable sweats sitting in our ergonomic chair, let’s take a minute to acknowledge our industry’s grand achievement. And, thank one and all for their contribution and consider what’s coming next. About the Author Robert (Bob) Smith is Executive Director of the ESD Alliance, a SEMI Strategic Association Partner. He is responsible for the management and operations of the ESD Alliance, an international association of companies providing goods and services throughout the semiconductor design ecosystem.

At the SEMI Foundation, we’re taking steps to support a big, audacious goal – achieving gender parity in the microelectronics industry. Dating to its roots at Bell Labs, Fairchild Semiconductor, and Intel in the late 1950s and 1960s, the semiconductor industry was pioneered by men at a time when far fewer women were in the workforce. While women have made major workforce gains since those early days, we’re still far from achieving anything close to an equitable representation of women. According to the U.S. Bureau of Labor, only 11.8% of electrical and electronics engineers – and just 8.7% of mechanical engineers – are women. What’s more, research from the American Association of University Women (AAUW), a non-profit that champions equity for women and girls through advocacy, education, and research, tells us that women drop out of engineering careers more steadily and quickly than men. According to AAUW research, just 30% of women working in engineering are still in the field after 20 years compared to 35% of men. By the time women have been in the field for 30-34 years, that number falls to 19% – while it increases to 39% of men among the same cohort. The small number of women in engineering careers and the fewer still who stay in engineering long term illustrate the troubling gender disparities in the industry. Even with these low numbers, however, there are still women who have managed to not just stay in the industry, but to thrive and lead within it. I talked with four of these women about their professional journeys and how they believe women can be best supported in careers in our industry. The AAUW research report Solving the Equation: The Variables for Women’s Success in Engineering and Computing shows that attrition in engineering is higher among women than men. Passion for math and scienceLam Research VP Gowri Kamarthy took her Ph.D. in chemical engineering from UC Berkeley directly to Lam Research, where she’s spent the past 22 years in technical positions. Today she heads the company’s conductor etch product line.Coming from a family of engineers, including her father and siblings, Dr. Kamarthy had a built-in support system that was essential to her success. She never felt intimidated by male peers after spending her formative years pursuing her passion for math and science.“I may have stood out as a minority in the field of engineering, but there was also a silver lining in standing out,” she said. “People notice you.”Kamarthy realizes that engineering careers are generally perceived as being less compatible with family life, for both women and men.“Anyone who wants work-life balance in an engineering career will have to navigate its special challenges, including the need to work long hours to match the rapid pace of innovation,” Kamarthy said.Drawing from her own experience, Kamarthy offers some career advice. “Perseverance and grit are key to success,” she said. “The other ingredient is luck. I was fortunate to have great bosses at Lam who didn’t see gender first and foremost. Instead, they recognized my ability to deliver on projects and encouraged me to perform at my best.” A love for math and science. The confidence to excel in those subjects. A support system to help her through the bumpy times. These were also truths for Sandy Vos, Ph.D., director of R D at NXP Semiconductors.“I was always good at figuring things out,” says Dr. Vos. “I remember feeling enthralled when I got my first internship because it combined engineering, math, science and manufacturing.” Like Kamarthy, Vos was aware of her status as a woman in a male-dominated field, but it didn’t stop her.“If anything, my gender drove me to prove myself,” Vos said. “And I’ve been fortunate because everywhere I’ve worked, I’ve been a part of a smart and collaborative team.”That doesn’t mean gender never came into play. Whenever it did become an issue, Vos didn’t shy away from hard conversations. She recalls having a conflict on the plant floor with two men who each stood over six feet and were about 100 pounds heavier.“I had a conversation with them, and we figured it out,” she said. “But for a while there, my heart was racing.”Gender felt like a bigger issue when Vos was younger. “Now that I have gray hair, it’s not much of a concern,” Vos said. “But earlier in my career, I started putting Ph.D. on my business card so people would know I could talk technical details.”Though just one of three women in an undergraduate class of 35 engineering students – and with a teaching cohort of all-male professors – Debbie Gustafson anticipated equitable treatment in her college engineering program. She had the same outlook when she began her career in semiconductor manufacturing. But the belief that she’d receive the same treatment as her male peers went largely unfulfilled. This didn’t slow her down. During her first year as CEO of Energetiq, she grew the company’s revenues and valuation. A year later, she steered the company through a successful acquisition by Hamamatsu Photonics. Today Gustafson continues to lead Energetiq as a wholly owned subsidiary, but the road to the top job wasn’t without hurdles. Gustafson muscled through the tough times.“When I started out, I traveled to Japan and Korea when there weren’t other women in technical roles,” she said. “My first meetings were extremely frustrating. I was the only woman in the room, and the men wouldn’t address me. This went on for a year, but I kept coming back and built the relationships.”Now a member of the SEMI Foundation Board of Trustees, Gustafson credits mentors with helping her navigate the nuances of doing business across cultures during those early years.A rocket scientist among usAlissa Fitzgerald might tell you that MEMS isn’t rocket science. But that’s only because she has a Ph.D. in Aeronautics and Astronautics, which actually is rocket science. Dr. Fitzgerald worked at a government laboratory and a large defense contractor before she got her Ph.D. and moved to a MEMS industry startup. Though gaining valuable experience, she found the environments too hierarchical and lacking in career development opportunities for young female engineers. As one of the few women engineers at these heavy-duty engineering firms where, in the 1990’s, there were no women in leadership roles, Dr. Fitzgerald sensed that opportunities for her to advance were remote. Fitzgerald started her own firm rather than climb up the ladder of another company, but it turns out, her motivation had nothing to do with gender.“It was the way engineers were treated like Dilbert,” she said. “I felt like a cog in the wheel, working for corporations that weren’t nurturing or appreciative of engineers.”After years of working for other companies, Fitzgerald founded the eponymous AMFitzgerald Associates, a developer of innovative MEMS and sensor solutions for specialty applications. When gender did come up for Fitzgerald, it manifested in men questioning her technical abilities.“Early in my career, I felt like I had to prove myself worthy, even though my degrees were from MIT and Stanford,” she said.Over 3,000 respondents to the Workplace Experiences Survey, sponsored by the Society of Women Engineers and the Center for WorkLife Law at UC Hastings Law, validate Fitzgerald’s experience. 61% of women vs. 35.1% of white men surveyed cited Prove-It-Again Bias – “having to prove themselves repeatedly to get the same levels of respect and recognition as their colleagues.” For engineers of color, that disparity was even worse. 68% of engineers of color (both women and men) reported Prove-It-Again Bias vs. 35% of white men.“For women and people of color, there’s rarely an assumption of competence,” Fitzgerald said.It’s sad but true that we can’t decouple the challenges women face from the challenges people of color face. Both are dramatically underrepresented as chip companies, and women of color represent the smallest percentage of the industry’s workforce and leadership.Inclusivity mattersWorking toward gender equity isn’t just a case of doing what’s right. It’s a case of doing what’s profitable. Research shows that companies with more women on the board perform better.“Given the pace of innovation in semiconductors, we need people from different backgrounds and perspectives to solve the hard problems challenging our industry,” Kamarthy said.Vos appreciates the fact that SEMI is creating a forum of inclusion.“Inclusion starts when you’re young,” she said. “School-aged kids are already making decisions about a future they see as exciting and possible. Our job is to make sure they have the opportunities to pursue what they envision.”Change won’t come magically, though. Fitzgerald believes companies need to make a concerted effort to attract a diverse population.“While I see a disproportionate number of female applicants, I’m more the exception than the rule,” she said. “When male executives call and ask, ‘How are you finding all these amazing female engineers?’ I say, ‘they’re finding me.’”Elevate the storyAchieving gender parity in microelectronics is a daunting task. Fortunately, access to SEMI’s global membership puts us in a unique position to make this deeply complex story clear and relevant to our members, so we can help support the shift.We’re looking at both the stark numbers of women working in microelectronics and at the lack of longevity of women in engineering. We’re elevating the conversation about childhood education. Why are girls passed over in math and science classes in early grade school, and what is the effect of teachers’ lowered expectations for girls taking these classes? What does it mean to be the only in the room? The only woman, or the only woman of color, on a team or in a meeting room. Feelings of isolation or disengagement – or frustration with Prove-It-Again bias – often lead to turnover in an industry that already struggles with retention.Reverse the trendThere’s much SEMI members can do to work toward gender parity in our industry. Look at recruitment, hiring, retention and promotion processes to see how women fare in them. Consider how to create a company culture of self-awareness and inclusion. Ensure equitable pay. Suggest and request women speakers for keynotes and panels at conferences. And offer workplace flexibility to allow women – who often bear most family responsibilities – to take time off or reconfigure schedules so they can help care for children or ailing parents.It’s time for our industry to reverse the trend of gender inequality. Research shows that companies with greater gender and racial parity are more productive, innovative, and profitable. If we welcome and support women in our companies, we will help women – and our industry – reach their full potential.Get involved with SEMIRegister for the Women in Semiconductors (May 3, 2021). This virtual event will include interactive exploration and discussion on strengthening the roles of women in hybrid and remote work environments. Everyone managing teams or experiencing the gender parity challenges and opportunities will benefit from the fresh thinking and best practices that the Women in Semiconductor program is known for.Participate in the SEMI Mentoring Program. By matching mentees with industry leaders and professionals, SEMI Foundation facilitates one-on-one mentoring relationships that benefit all participants. Whether you are a recent university graduate or growing in your microelectronics career and looking for support, participating in the SEMI Mentoring Program will put you on the right track.Participate in the McKinsey Company 2021 Women in the Workplace Study, which looks at representation and the experience of women in companies across the U.S. and offers recommendations on how to retain and support women. Email [email protected]. Shari Liss is executive director of SEMI Foundation. Connect with her on LinkedIn.

MEMS actuators transform electronic signals into something that can be sensed or touched by the end user of an electronics device. A case in point: MEMS actuators such as print heads in inkjet printers transform electronic files into text or beautiful images. In 3D printers, actuators can produce real objects. Inside smart glasses, tiny MEMS mirrors can create virtual objects. Little surprise, then, that integrating these powerful devices into the end products is a multidisciplinary enterprise. STMicroelectronics has been successfully leading the deployment of dedicated MEMS actuator solutions with customer products in various market segments. SEMI spoke with Anton Hofmeister, group vice president and general manager of the MEMS Actuator Division at STMicroelectronics, about MEMS actuator trends. Hofmeister shared his views at the SEMI MEMS Imaging Sensors Forum as part of the virtual SEMI Technology Unites Global Summit. Watch the STMicroelectronics’ presentation on-demand until March 26, 2021. Registration is open. SEMI: What is the difference between MEMS devices that sense and MEMS devices that actuate? Hofmeister: MEMS sensors gather data from the world around us including motion, pressure and air temperature and transform them into an electrical signal. Actuators work the other way round. They receive an electrical signal and transform it into some well-controlled actuation such as ejecting a fluid, moving a membrane or deflecting a laser beam. SEMI: How can MEMS actuators’ integration be simplified to be embedded in new applications so they appeal to consumers? Hofmeister: The challenge of integrating MEMS sensors into devices has been simplified by demo kits and evaluation boards, which customers use to embed the sensor into a system. MEMS actuators are more difficult to integrate. They often power the core function of a system and therefore require deep system understanding. Reference designs are a big step forward in simplifying integration. My presentation at the SEMI MEMS Imaging Sensors Forum showcased some examples. MEMS micro-mirror projection for augmented reality (AR) glasses is an example of a complex system that requires multiple types of components to function. Together with several partners, STMicroelectronics recently announced the LaSAR Alliance, which will develop reference designs to enable the AR glasses market. SEMI: MEMS sensors and actuators are considered the backbone of many consumer products. Are MEMS actuators also mostly used in automotive? Hofmeister: The widest use of MEMS actuators has so far been in print heads for inkjet printers. In recent years, we have seen actuators adopted in emerging applications ranging from piezo heads for 3D printers to MEMS mirrors for laser beam scanning systems or 3D sensing solutions for consumer applications. The first high-volume application in automotive will likely be MEMS mirrors for LIDAR systems. SEMI: What market growth trends do you see for MEMS sensors and actuators? Hofmeister: The sensorization trend, which aims to collect data from homes, cities, factories, cars and personal devices, continues to drive the adoption of sensors and actuators for a wide variety of applications. While the last wave of MEMS growth was triggered by one end product – the smartphone – the next wave will be driven by multiple applications and use cases in industrial, medical, automotive and personal electronics. SEMI: How can technology unite us? Hofmeister: In recent months, we have all experienced vividly how vital technology has become. MEMS, and semiconductors in general, are an integral part of many products and services that make our lives easier. Communications technologies have been particularly important during this pandemic, whether using the personal devices as our interface to the digital world or the complex infrastructure that they operate through. I hope that my participation at the summit helped increase awareness of the new possibilities and opportunities that technologies like MEMS actuators have to offer to create products and services that further improve people’s lives. Anton Hofmeister is group vice president at STMicroelectronics, general manager of the company’s MEMS Actuator Division and managing director of its German subsidiaries. Hofmeister has been with STMicroelectronics for more than 30 years, working in Germany, France, the U.S. and Italy. He has held managerial positions in key account management, product and strategic marketing, advanced R D and general management. For the past 10 years, he has managed various product divisions in the MEMS sector. Hofmeister has also served as a board member of the Singapore-based molecular diagnostics company Veredus Laboratories. Serena Brischetto is senior manager of Marketing and Digital Engagement at SEMI Europe.

Recent semiconductor supply chain constraints have drawn the attention of Washington policymakers at every level. Exasperated by the global pandemic, customers of semiconductor manufacturers have sounded the alarm about the chip shortage and the downstream consequences for end-user companies and consumers. Global automakers have suffered the brunt of the impact, shuttering factories and slashing vehicle production. Last month President Biden issued an Executive Order (EO) to review and secure America’s supply chains. The stated goals of this review are to revitalize and rebuild domestic manufacturing capacity, maintain America’s competitive edge in research and development, and create well-paying jobs. Under the EO, the U.S. will also work more closely with allies to strengthen supply chains. The EO directs supply chain reviews on several critical segments, including semiconductor manufacturing and advanced packaging. The Department of Commerce will identify risks throughout the U.S. semiconductor supply chain and make policy recommendations to address those risks within 100 days of the EO’s issuance. In coordination with the White House, Congress is contemplating a variety of measures to address supply chain issues. Recently, the Senate Finance Committee held a hearing on the effects of the U.S. tax code on domestic manufacturing. Both Chairman Ron Wyden (D-OR) and Ranking Member Mike Crapo (R-ID) highlighted their desire for bipartisan cooperation to use the economic tools within the jurisdiction of the committee to bolster domestic manufacturing. The committee discussed two pieces of legislation that would provide significant incentives to domestic manufacturing of semiconductors. The first was the investment tax credit (ITC) for semiconductor manufacturing that was included in last year’s CHIPS for America Act but not with the other semiconductor incentives in the FY2021 National Defense Authorization Act (NDAA). An ITC would provide predictability and stability in the U.S. tax code to promote large, long-term investments for the industry. The second was the American Innovation and Jobs Act, which repeals the R D amortization requirement set to go into effect in 2022 and expands the refundable tax credit for startups and small businesses. Enhancing domestic incentives for R D and manufacturing is an important step in putting the U.S. on equal footing with other countries and would promote its continued leadership in the chip industry. Senate Majority Leader Chuck Schumer (D-NY) has announced his intention to craft a package of measures to strengthen U.S. competitiveness vis-a-vis China. The package reportedly would include funding for the microelectronics R D and Commerce grant programs that were passed in the NDAA. The Senate plans to take up the legislation in April. SEMI applauds the renewed focus on incentivizing domestic manufacturing and R D for an industry that enables countless technologies, drives innovation in sectors throughout the U.S. economy, and powers the electronic systems essential to critical infrastructure and defense systems. We look forward to working with policymakers in Congress and the Administration to support the entire domestic semiconductor ecosystem. Kimberly Ekmark is director of Public Policy and Advocacy at SEMI

The global semiconductor industry is on track to register a rare three consecutive years of record highs in fab equipment spending with a 16% increase in 2020 followed by forecast gains of 15.5% this year and 12% in 2022, SEMI highlighted in its quarterly World Fab Forecast report.

With each transition to a new technology node, fab requirements for metal and particle contamination become more stringent, posing challenges for existing coating methods such as anodization or plasma spray that may not provide complete protection against contamination especially on critical chamber components with complex geometry. SEMI spoke with Beneq business executive Sami Sneck about common metal and particle contamination issues with critical chamber components, coating methods to protect against corrosion, and properties to look for when selecting the optimal protective coating solution. Sneck discussed the unique benefits of atomic layer deposition (ALD)anti-corrosion coatings with Aluminiumoxide (Al2O3) and Yttrium Oxide (Y2O3) and offered recommendations on how to work with original equipment manufacturer (OEM) partners to design, test and implement an ALD coating solution for semiconductor equipment. To learn more, visit Beneq at its digital booth at SEMI Technology Unites Global Summit, available on-demand until March 26, 2021. Registration is open. SEMI: How does ALD compare with other coating methods such as anodization and plasma spray? Sneck: ALD enables conformal dense and pinhole-free coatings on complex shapes. We can deposit various ALD coating materials on parts made of various materials. All other coating techniques have limitations. For instance, anodization is conformal, but porous and is suitable for Al2O3 used for aluminum parts. Plasma Spray is a line-of-sight method and not conformal on complex shapes, such as holes in showerhead parts. SEMI: Which substrate materials work for ALD coatings? Sneck: In general, parts made of common metal materials, such as aluminum, stainless steel or titanium, all work well with ALD coatings. Commonly used ceramic materials work well with ALD too. Plastic materials need to be coated generally at a lower temperature, which limits the coating material selection, but materials such as Al2O3 can be applied as well. SEMI: What is the maximum coating thickness you can reach with ALD? Does this depend on the material? Sneck: Yes, indeed. The maximum coating thickness does depend on the material of the part that we are coating. Polymer materials for example, have a very large coefficient of thermal expansion, which limits the practical coating thickness to the 100-nanometer level. On metal and ceramic parts, coatings of several micrometers are possible too. Typically, ALD coating thickness on chamber components range from a few hundred nanometers to one micrometer. SEMI: Which aspect ratio can you coat with ALD? Sneck: Basically, ALD can coat aspect ratios of 1000:1, but this would be extremely slow. In practice, some of the most complex parts are showerhead parts with small holes. Typically, these have an aspect ratio of around 100:1, which is perfectly commercially feasible for ALD. An extreme example would be gas lines: In this case, the aspect ratio may be also around 100:1, but the physical distance from one end to the middle may be half a meter. In this respect, it is not practical to wait for gas diffusion to reach such a depth level. Instead, the gas lines can be coated by forcing the ALD precursor gas flow into the gas line parts. This works well but needs part-specific manifolds to guide the gases. SEMI: What is the lifetime of ALD coating compared to other coatings? Sneck: ALD coatings differ from other coatings a couple of ways. First of all, ALD coatings generate less particle contamination since they are non-porous. Secondly, and most importantly, ALD coatings can cover areas that other coatings cannot. What is considered the lifetime of a certain part depends on various factors. Ultimately, the lifetime needs to be confirmed by testing parts in actual process chambers by running a lot of wafers through the chamber and monitoring critical parameters such as particle level and yield. SEMI: If you have multiple shelves with parts in the reaction chamber, how does the shelf position affect the coating uniformity? Is center shelf better than top and bottom shelf? Sneck: Uniformity depends on many parameters, including the part geometry, part holder geometry, batch size and coating material. When the shelves supporting the parts are optimally designed and the gas flow is well-distributed to all shelves, all shelves from top to bottom show similar uniformity. SEMI: Is there any risk of cross-contamination? Sneck: Cross-contamination could potentially be caused by the parts themselves or by different coating materials. The batch setup is fixed in production use, which means the parts are the same in every batch. The only variation is that the batch may not be full in some cases, but then we do not fill the empty part of the batch with other parts that could cause contamination in order to prevent contamination from one part type to another. Cross-contamination from one coating material to another is not a usual concern but can be prevented by using dedicated reaction chambers for different coating materials. This is very easy to do with Beneq P800. Sami Sneck manages Beneq’s semiconductor part coating business. He joined Beneq in 2005 and since then has held various professional and management positions including product manager, application manager, director of ALD group, head of sales, and head of Asia. He earned his MSc degree in Chemical Engineering in 2001 from Helsinki University of Technology. Sneck has special expertise in Atomic Layer Deposition technology and business development. He has played a vital role in introducing various ALD production concepts and solutions to several industries ranging from jewelry to photovoltaics, electronics and semiconductors. Access the free webinar recording and discover the latest anti-corrosion coating solutions and the unique benefits of ALD (atomic layer deposition). This webinar is particularly helpful for process engineers, equipment engineers and others responsible for contamination control and equipment yield. Serena Brischetto is senior manager of Marketing and Digital Engagement at SEMI Europe.