semiconductor manufacturing

Back in March 2020, at the onset of the spread of COVID-19 in the U.S., SEMI quickly formed an Environment, Health and Safety (EHS) COVID-19 working group made up of EHS professionals who suddenly saw a critical need to share their experiences, validate untested policies, and collaborate on establishing best practices in response to an extraordinary public health crisis. The group, which today numbers 20 member companies, meets regularly to discuss an array of topics that have grown beyond their pressing need to react to a crisis earlier to a longer, more measured view of risk management as coronavirus cases continue to climb worldwide. While themes vary from one meeting to another, the recurring agenda remains the same to address the following topics: Phase approach – How to bring staff back on site Social distancing – How to manage people traffic flow on site Contact tracing – Track exposure to ensure workplace safety Space allocation – Changes to offices, cubicles and conference rooms HVAC systems – Optimizing workplace air flow and improving filtration systems Clean rooms – PPE and distancing protocols Training – Communications approaches to expanding awareness in order to reduce risk of spreading the virus Travel policies – Domestic and international travel guidelines Vaccines – Policies for vaccinating and monitoring personnel Site inspections – Preparing for an eventual increase in inspections from OSHA representatives In April, the SEMI EHS team issued a survey to assess the pandemic preparedness of member companies. Designed by the COVID-19 working group, the survey found that, despite having a pandemic plan in place, many member companies faced a shortage of PPE and sanitization equipment, their most significant challenge at the time. Members also pointed to operational challenges posed by the pandemic and raised questions about how to establish sound policies appropriate for their operations and geographic locations. Today, the SEMI EHS COVID-19 working group is well-established collaborative forum on public guidelines that members see as unclear as they continue to chart their own pandemic policies. With the first tranche of vaccines recently starting to ship in the U.S., the group has turned its attention to vaccine distribution and how companies will encourage employees to be vaccinated. For more information about the SEMI EHS COVID-19 working group or to join the group, please contact the SEMI EHS team at [email protected]. Olivier Corvez is senior manager of Environment, Health, Safety and Sustainability at SEMI.

Semiconductors play an essential role in modern society by enabling ground-breaking technological advances. The manufacture of high-volume and advanced semiconductors requires the use of fluorinated chemicals known as PFAS. Representing the voice of SEMI members, I explained the important role of these substances and their “essential use” in the semiconductor manufacturing supply chain at a Chemical Watch conference for industry and European Union decision-makers on 3rd of December 2020.In order to achieve the European Green Deal’s zero pollution ambition for a toxic-free environment, the European Commission announced in its recently published Chemicals Strategy for Sustainability its intention to restrict the use of the most harmful chemicals, except in cases where they are deemed essential for society. Per- and polyfluoroalkyl substances – known as PFAS – are the first group of chemicals facing regulatory scrutiny on this basis. This begs the question: What chemicals should be characterized as essential for society and what uses will they encompass? The key and enabling role of semiconductors in modern lifeSemiconductors are essential and ubiquitous in our lives. They are integral to enabling modern society to function – driving advancements in mobile communication technologies for the smartphones and computers that help us work more efficiently and connect us with our loved ones. These benefits have never been more evident than in 2020 with billions of people finding themselves working and studying remotely and safely from home.At the same time, technologies relying on semiconductors have been vital in the effort to combat COVID-19 – in ventilators, medical imaging devices and digital healthcare solutions. In addition, semiconductors will also enable the next leap in society to Industry 4.0 and as essential building blocks in connected and electric vehicles, artificial intelligence (AI) and quantum computing.The Commissioner for Internal Market, Thierry Breton, has highlighted the strategic importance of semiconductors in achieving European digital sovereignty (for instance, in his speech at Hannover Messe Digital Days), and the EU’s New Industrial Strategy[1] also points to the importance of semiconductors and microelectronic systems. What must also be appreciated are the cost and complexity of producing these valuable technologies. Setting up a cutting-edge fabrication plant with the hundreds of pieces of semiconductor manufacturing equipment typically required can cost around €15 billion.[2] A single semiconductor manufacturing tool typically consists of millions of articles, and a typical fab may house several hundred pieces of equipment. Furthermore, according to SEMI estimates, the fabrication of semiconductor wafers requires approximately 500 highly specialized process chemicals. In many cases, these processes, equipment and facilities rely on the unique properties offered by PFAS.“SEMI has worked diligently to highlight the strategic importance of semiconductors in achieving European digital sovereignty, and we are pleased that the critical role of microelectronics has been fully recognized by the EU and Member States. Fluorinated chemicals are essential for semiconductor manufacturing. "These specific chemicals are necessary due to their unique properties, and no alternatives are currently available that can adequately provide the functional properties required in semiconductor manufacturing. The essential use concept, therefore, must enable technological innovation, must apply across the entire supply chain, and must enable EU’s critical infrastructure and strategic objectives.” What are PFAS, and why and where are they used in semiconductor manufacturing?PFAS are a broad and highly diverse group of substances with unique properties and characteristics. The Organisation for Economic Co-operation and Development (OECD) has compiled a list of approximately 4,700 substances,[3] a handful of which are used in the semiconductor manufacturing industry. These very specific chemicals are necessary due to their unique and unparalleled properties that enable them to be used in the demanding conditions of semiconductor manufacturing.Semiconductor chemicalsAt the very core of semiconductor manufacturing is the photolithography process, where microscopic geometric patterns are transferred onto a film or substrate. Photolithography specialty formulations containing fluorinated compounds are used in various steps of this process to ensure quality and reduce the probability of defects. PFAS must be used due to their low surface tension and compatibility with other chemicals. PFAS are typically no longer present in the finished product. However, there are applications where PFAS are present in the final semiconductor device, particularly in imaging semiconductors used in cameras, displays and some medical devices, amongst others. Semiconductor manufacturing equipmentPFAS are also essential to semiconductor manufacturing equipment and factory infrastructure. The exceptional combination of their heat and chemical resistance and their chemical inertness allows fluoropolymers to be used both in equipment components (tubing, gaskets, containers, filters, etc.) and lubrication (such as various oils and greases). These same properties are also needed to ensure the functioning of the surrounding infrastructure. Finally, some fluorinated gases, which are already regulated by specific legislation,[4] are used as refrigerants and to clean the facilities.These are a handful of examples of how PFAS are used in semiconductor manufacturing. Today, there is no other way to undertake these processes or to build semiconductor manufacturing equipment without PFAS. No alternatives are currently available that can adequately provide the functional properties required. Even if alternative chemicals and technologies were discovered today, due to the extremely complex qualification process throughout the value chain, it would take another 15 years to deploy them in high-volume manufacturing. Therefore, continued access to PFAS is a prerequisite for high-volume and advanced semiconductors. Lack of continued access to PFAS could lead to an inability to produce and supply the EU with semiconductor manufacturing technology.How should we think about essential uses?Regulators have started to think about what uses of PFAS are essential and in which cases their use should be allowed. In developing this concept, there are a few aspects to keep in mind.Essential use must enable, not hinder, technological innovationFirst and foremost, the essential uses concept should enable continued technological innovation instead of acting as a hindrance. Semiconductors and manufacturing technology are constantly evolving and becoming more diverse to help meet increasing societal demands. What we see as innovative today may be commonplace in the future, while future innovations may be unimaginable today. We must therefore be careful not to accidentally limit our future potential for innovation.Essential use must apply across the entire supply chainSecondly, classifying a use as essential should apply throughout the entire supply chain. We must, for example, avoid defining semiconductors as essential while classifying the semiconductor manufacturing equipment and chemicals used to produce semiconductors as not essential. In the semiconductor manufacturing supply chain, where one manufacturer can have up to 16,000 suppliers, this risk is evident.[5]Essential use must enable critical infrastructures and the EU’s strategic objectivesFinally, we should keep Europe’s societal priorities in mind. The EU needs to be able to maintain and protect its critical infrastructures. Similarly, we should not lose sight of the EU’s strategic objectives of a green and digital Europe.Semiconductors, in conjunction with their corresponding manufacturing equipment and chemicals, are essential technologies in everyday life and the backbone of the EU’s strategic value chains. Manufacturing semiconductors is a very expensive and complex process that would not be possible without the unique properties of PFAS, making them essential to achieving the EU’s strategic objectives today – whether the European Green Deal or digital autonomy – and in the future. Therefore, we must ensure that essential uses will enable the continued use of PFAS in semiconductor manufacturing.The SEMI presentation delivered at the Chemical Watch event can be accessed here.Emir Demircan is director of Public Policy and Advocacy at SEMI Europe.[1] “The EU will also support the development of key enabling technologies that are strategically important for Europe’s industrial future. These include robotics, microelectronics, high-performance computing and data cloud infrastructure, blockchain, quantum technologies, photonics [etc.]”[2] Emerging technologies in electronic components and systems (ECS) Opportunities Ahead – A study by DECISION, 2018 for the European Commission[3] Available here[4] Regulation (EU) No 517/2014, “F-Gas Regulation”[5] SIA Nathan Associates, 2016, https://www.semiconductors.org/wp-content/uploads/2018/06/SIA-Beyond-Borders-Report-FINAL-June-7.pdf

The semiconductor industry must do far more to educate the electronics supply chain on the subtle differences among various fluoropolymers, 30 SEMI member companies learned in an October 13 webinar organized by SEMI to help maintain a unified voice on the critical importance of per- and polyfluoroalkyl substances (PFAS) in semiconductor manufacturing. At the same time, producers and customers of the substances used in chipmaking should work more closely together to steer clear of adopting policies that could limit the availability of safe fluoropolymers and the semiconductor industry’s ability to use them in the future.The insights were offered by representatives from the Performance Fluoropolymer Partnership – a group within the Washington, D.C.-based American Chemistry Council – on per- and poly-fluorinated substances including fluoropolymers. The Council is an industry trade association representing American chemical companies. Following are other key takeaways from the webinar. Fluorinated polymers and non-polymers are commonly found in components used in semiconductor manufacturing such as fittings, valves, tubes, O-rings, wafer carriers, filtration media, high purity air filters, greases and lubricants. The substances are ideal for use in corrosive chemicals, high temperatures and other harsh environments and are found in a variety of electro-technical components such as potentiometers, wiring, printed circuit boards and Lithium-ion batteries. Fluoropolymers are a diverse family of plastics also widespread in modern life, with applications ranging from food packaging and non-stick coatings on kitchen pans to rechargeable batteries for electric vehicles. The term PFAS (per- and poly-fluoroalkyl substances) covers more than 4,700 chemicals with diverse physical, chemical, environmental and biological properties and impacts. There are also significant differences among their chemical compositions. A careful appraisal of their risks and impacts should take into account any potentially hazardous properties, toxicity levels, their prevalence in the industry, and whether substitutes are readily available. Growing pressure from regulators worldwide threatens future access to fluorinated chemicals, increasing the importance of raising awareness on how to distinguish groups of chemicals and encouraging a measured approach towards eliminating only chemicals carrying the greatest risk. Fluoropolymer producers and opponents of the chemicals must look past their divergent interests to work together to voice common concerns to regulators. Various SEMI working groups respond to public consultations when opportunities to present the semiconductor industry’s position arise. Individual group members communicate both among each other regarding new regulatory developments and also with external constituents through SEMI about the importance of chemicals to chip manufacturing. As with other sectors, the semiconductor industry continuously seeks to “green” its manufacturing processes. SEMI believes the commitment of the supply chain to these efforts is crucial to protecting the industry’s interests and driving innovation.Olivier Corvez is senior manager of Environment, Health, Safety and Sustainability at SEMI.

As the United States government has expanded semiconductor-related export controls, companies in the global electronics manufacturing and design supply chain have had to spend considerable time and effort navigating restrictions and managing significant new uncertainties emanating from recent policies. On November 9, SEMI submitted comments to the Department of Commerce’s Bureau of Industry and Security (BIS) urging the agency to proceed cautiously and adopt regulatory best practices and microelectronics industry recommendations to ensure that its identification of foundational technologies does not restrain U.S. innovation and exports without furthering essential U.S. national security interests. The comments specifically respond to the August 27 Advance Notice of Proposed Rulemaking (ANPRM), Identification and Review of Controls for Certain Foundational Technologies. The Export Control Reform Act (ECRA) of 2018 required BIS identify certain emerging and foundational technology that is “essential” to U.S. national security and requires such technology to be controlled to China and other nations subject to a U.S. arms embargo. Congress did not provide a specific definition for emerging or foundational technology, nor the term essential, further complicating the process to identify such technology.BIS has already implemented or proposed several emerging technology controls and the ANPRM starts the process to identify potential foundational technology controls. The SEMI comments focus on the fundamental question of how to define foundational technology, and are organized into three main sections: Requirements of ECRA Guidance from ECRA Regulatory best practices and industry recommendations Applying the statutory requirements and guidance, together with best practices and recommendations, to the identification of foundational technology indicates that most semiconductor-related technology, particularly semiconductor manufacturing equipment and materials, should be outside the bounds of the foundational technology initiative. In general, most technology related to semiconductor devices, manufacturing equipment, materials and design software is not essential to U.S. national security and, in cases where such technology does present material national security issues, it is generally subject to the U.S. list review process and multilateral controls. This technology is widely available outside the United States and due to substantial foreign availability, unilateral U.S. controls on such technology are likely to be ineffective in limiting its proliferation and harm U.S. development of or threaten U.S. leadership in this technology.While the SEMI comments focus on the effort to identify foundational technology, the recommendations and best practices apply in all export control contexts. Several of the statements pertain to policy in ECRA, including its imposition of controls to further specific essential U.S. national security interests only after full consideration of their impact on the economy.Other statements derive from factors ECRA requires BIS to consider, such as not seeking to control technology that’s already available outside the U.S. and not imposing controls that would harm U.S. technological development or leadership. An additional key factor is not imposing controls before multilateral controls are agreed to, nor when it is unlikely the relevant multilateral regimes will adopt similar controls, as is likely for technology that has been decontrolled by a regime.Finally, regulatory best practices suggest that technology-based controls should not be imposed when more targeted end-use or end-user controls can address national security concerns and duplicative controls in addition to recent, significant expansions of existing controls are unnecessary.SEMI is pleased to work with the U.S. Department of Commerce and other regulatory agencies, providing industry data, trends and perspectives to ensure export controls effectively serve national security interests without undue harm to technological development and leadership in this dynamic, globally competitive industry.Ways to Stay Connected and Learn MoreSEMI is committed to serving the global electronics manufacturing and design supply chain and present the collective voice of members to governments worldwide.The SEMI Global Update weekly newsletter provides updates on advocacy issues and technology trends and is available to all.Additionally, SEMI hosts live and virtual events that offer analysis and insights of geopolitical trends by industry experts, with the next opportunity to participate coming on December 3 with the SEMI CEO Webinar: Analyzing the Impact of the U.S. Election on the Microelectronics Industry.Joe Pasetti is Vice President of Global Public Policy and Advocacy at SEMI.

As the world combats climate change, the chip industry continues to build momentum in becoming a better steward of the environment. In July, Taiwan chip giant TSMC became the world’s first semiconductor company to join RE100, the global initiative to move away from a widespread reliance on fossil fuels and toward 100% renewable electricity. Applied Materials soon followed with a commitment to expand its renewable energy capacity. For the past four years, ASE Group, the largest outsourced semiconductor assembly and test (OSAT) provider, was named an industry leader in the Dow Jones Sustainability Indices (DJSI), making clear its commitment to protecting the environment. For its part, TEL was selected to be part of the FTSE4Good, a series of ethical investment stock market indices, and FTSE Blossom Japan, an index that gauges the performance of Japanese companies demonstrating strong Environmental, Social and Governance (ESG) practices.SEMI bolsters commitment to green energySEMI has also strengthened its commitment to promoting renewable energy in the semiconductor industry by adding the Green Power Pavilion at this year’s SEMICON Taiwan and continues to support the green energy movement as a co-organizer of Energy Taiwan. The largest renewable energy event in Taiwan, Energy Taiwan features international exhibitions, forums, policy initiatives and business matching events. This year the event attracted more than 12,000 visitors from 50 countries to highlight renewable energy breakthroughs and new products. The SEMI events complement RE100, which works across a wide range of industries that include financial services and retail. The initiative connects more than 260 members that count among them the world’s most influential businesses such as Apple, Google and Facebook and their suppliers through educational events.In many respects, TSMC is becoming a beacon of green energy in the chip industry. In July, the company committed to 20-year agreement to buy offshore wind power gear made by energy firm Ørsted in Taiwan, the global leader in the wind power industry. According to the purchase agreement, TSMC will offtake full production from 920-megawatt wind farms off the coast of Changhua County in western Taiwan expected to start operations in 2025 or 2026. The agreement will by far mark the world’s largest corporate green energy order in the semiconductor manufacturing and renewable energy industries and demonstrates TSMC’s long-term commitment to environmental sustainability.In addition to sourcing renewable energy, TSMC has been working closely with its downstream and upstream suppliers to help drive supply chain improvements geared toward a greener industry by offering on-site coaching, energy audits and educational resources. But the company's focus on energy efficiency is nothing new. For years, its Supply Chain Management forum has promoted industry sustainability and corporate responsibility. Moreover, TSMC worked with SEMI at this year’s SEMICON Taiwan to generate greater awareness of the importance of green energy to the industry and encourage SEMI members to become more involved in the movement.Supply chains expand eco-friendly practicesThe drive toward greener semiconductor manufacturing is also expanding to encompass entire supply chains. One notable initiative is Green Supply Chain Management (GrSCM), an effort to integrate environmental thinking into every level of the supply chain, from product concept to distribution. GrSCM involves the retooling of product design, materials sourcing, manufacturing and processes to reduce the ecological footprint of factories. So far, the results are encouraging. More companies are factoring environmental sustainability into their purchasing decisions to urge suppliers to better manage their power usage and join the green energy movement – an important step in curbing the unavoidable consequences of climate change. Terry Tsao is Global Chief Marketing Officer at SEMI and President of SEMI Taiwan.

SEMI is pleased to welcome Singapore-based UTAC Holdings Ltd., formed nearly 50 years ago, as a new member. UTAC is a leading independent provider of assembly and test services for a broad range of semiconductor chips, offering a full range of semiconductor assembly and test services across analog, mixed-signal and logic, and memory. Its customers are primarily fabless companies, integrated device manufacturers and wafer foundries. The company has production facilities in Singapore, Thailand, China, Indonesia and Malaysia as well as sales offices in five regions: the United States, Japan, China, Taiwan, the rest of Asia and Europe.I recently spoke with Dr. Nathapong Suthiwongsunthorn, Vice President and General Manager of UTAC Thailand, about UTAC’s smart manufacturing advances, the company’s role in the semiconductor industry’s transformation, and the industry outlook for Thailand over the next year.Ng: How does UTAC Thailand complement your other facilities?Dr. Nathapong: As one of the world’s largest producers of quad-flat-no-leads (QFN), UTAC Thailand has significant capability in assembly and test of advanced leadframe products including power products such as Cu Clip packages as well as MEMS products. We also serve top global IDMs and have the largest share of assembly and test for the automotive market among all UTAC operations. UTAC’s other facilities have expertise in wafer-level packages and system-in-a-package and serves the communication and consumer market not only for IDMs but also for the fabless and foundry companies. The Thailand factory nicely complements the other UTAC facilities both from the standpoint of operational and marketing diversity. Ng: UTAC Holdings Ltd. announced in August this year that it has completed its sale to Wise Road Capital, a global private equity firm. Will this in any way change the operation and business strategy of UTAC Thailand?Dr. Nathapong: I don’t believe it will change the way we operate. However, the acquisition is very positive for us from a financial perspective. With the benefit of significantly reduced debt and interest expenses, we will be able to expand our business to grow with and hopefully beyond the semiconductor market. Ng: To what extent has UTAC adopted smart manufacturing?Dr. Nathapong: UTAC Thailand is leading the way in terms of automation, smart manufacturing and Industry 4.0 with our in-house automation team and unique expertise. For example, we have built our own inspection equipment that is much faster and cheaper than what is commercially available. We also working on many programs such as mobile robot, AGV, auto inspection and office automation to help drive greater production efficiency. We are replicating our manufacturing advances and fanning them out to other UTAC facilities.UTAC Thailand Ng: What are some of the challenges you face in pushing for the industrial transformation in Thailand?Dr. Nathapong: I think the key challenge is to find skilled engineers who can perform hardware- and software-related tasks critical to the industrial transformation. But frankly, we have done a good job in managing this challenge by hiring very smart people, providing them with the required in-house training, and using outside training for new recruits as necessary. We have developed partnerships with capable vendors in this regard as well.Ng: What are the key differentiating elements (e.g. talent, tax, technology, trade, EHS) in Thailand that have been instrumental in supporting the E E ecosystem?Dr. Nathapong: There are two key differentiating elements for us. Firstly, UTAC has been around for over 47 years and is very well-established in Thailand with a positive reputation as an employer. This makes hiring talented people relatively easy. Secondly, and perhaps more importantly, the nature of the Thai people and also the benefits the company provides make it relatively painless to retain key employees. I also believe that we have a significant number of engineers available in Thailand. Finally, labour costs in Thailand are still very reasonable and stable. So we are able to acquire talent at a very competitive rate compared to other countries. Ng: What is the industry outlook for E E industry in Thailand over the next year?Dr. Nathapong: Surprisingly, the current sad predicament of COVID-19 has shown no negative impact for the global semiconductor industry – people seem to be buying more electronics with the lockdown. Our outlook for the Thailand’s E E industry is similarly very positive. Most semiconductor companies including UTAC see significant growth this year and I hope it will continue.Ng: With the recent semiconductor geopolitical and trade tensions, are more customers moving their business to Thailand?Dr. Nathapong: I believe so. We do see some of our key customers move manufacturing out of China and into Thailand. The relocations help them offset or avoid any potential fallout from current geopolitical tensions.Ng: In what areas do you think SEMI Southeast Asia can play a role to help our members companies in Thailand like UTAC?Dr. Nathapong: The semiconductor industry has been in Thailand for a long time. In fact, UTAC Thailand is 47 years old this year! However, I feel that Thailand never really worked with a strong establishment organization like SEMI that can connect various companies together to help drive innovation. I think SEMI Southeast Asia can truly help Thailand to move up to the next level of providing semiconductor solutions globally. We welcome SEMI Southeast Asia’s help in this regard.About Dr. Nathapong SuthiwongsunthornDr. Nathapong Suthiwongsunthorn joined UTAC in 2009 and is currently General Manager of UTAC Thailand, UTAC’s largest operation site. Before taking over the management of Thailand operations, he was Vice President of Research and Development, running UTAC’s global R D group. Dr. Nathapong has more than 20 years of experience in the semiconductor industry. He holds more than 40 international patents and publications in wafer-level and advanced packaging.Prior to joining UTAC, Dr. Nathapong held several key leadership positions in research and development at Schott, STATS ChipPAC and Infineon. Dr. Nathapong has a Ph.D. in Electronics Engineering from Oxford Brookes University, England.Bee Bee Ng is president of SEMI Southeast Asia.

Europe is facing an acute shortage of skilled microelectronics workers that undermines the growth potential of not only the electronics industry but the European economy as a whole. Nearly 1.1 million job advertisements for electro-engineering workers were placed in the EU between mid-2018 and the end of 2019 (CEDEFOP, 2020). The shortfall looms large as a skilled and diverse workforce that can continuously innovate is the oxygen of microelectronics. In light of the critical importance of microelectronics to Europe’s ability to fulfill its growth potential, SEMI Europe participated in the high-level roundtable hosted by Commissioner Nicolas Schmit and Commissioner Thierry Breton on October 5. The discussion’s key takeaway: The skills challenge facing the microelectronics industry is too complex for one organization to tackle, and reskilling and upskilling its workforce should be a common priority for Europe. Only with a diverse, substantial and skilled microelectronics workforce can Europe achieve its R D, design and manufacturing ambitions while ensuring its sovereignty in the digital age. The roundtable highlighted the EU Pact for Skills as a key means to narrow the industry’s skills gap.An ever-growing part of our lives, microelectronics, with their ability to run billions of computations per second and store vast quantities of data, are the brains of modern technology. The digital sovereignty of nations around the world today relies on advanced microprocessors to collect, transfer, analyze and store immense amounts of data used in key end-user sectors such as mobility, telecommunications, energy, security and healthcare. Information and communication technologies (ICT) enabled by microelectronics are helping much of the world’s population to work and study from home and remain safe during the COVID-19 pandemic.According to the Smarter2030 Report, further deployment of ICT, including electronic components in critical sectors such as transportation, manufacturing, agriculture, construction and energy, could eliminate the equivalent of 12.1 billion tons of CO2 per year globally. These are some of the reasons why nations worldwide are making large-scale investments to advance a homegrown microelectronics R D, design and manufacturing base. It is no surprise, then, that semiconductors are now at the center of the so-called global techno-trade wars.Clearly, Europe urgently needs to mobilize and pool resources to develop effective lifelong learning programs for all workers and continue investing in microelectronics innovation. We need to instill the passion for creating technology among current and future workforce, in particular women and people with challenged backgrounds, and build a highly diverse talent pool. Working together, we can better demonstrate how computing technologies, including quantum, high-performance and edge AI, provide solutions to grand societal challenges and attract talented people to the fascinating world of electronic components and systems.Against this backdrop, the microelectronics industry finds the Pact for Skills very timely and crucial to advancing the talent pool underpinning Europe’s deep digital ecosystem. The Pact will play an instrumental role in improving the scope and the quality of training partnerships at regional, national and European levels, sharing best practices and helping the microelectronics industry and workforce adapt to the effects of COVID-19.The microelectronics industry is committed to building on the momentum created by the METIS Erasmus+ collaborative project and to mobilizing our ecosystem and education partners for a successful Pact for Skills in Microelectronics starting this year.The High-Level Roundtable: Skills for Microelectronics was hosted by Commissioner Thierry Breton and Commissioner Nicolas Schmit. Participants included Paul Boudre, CEO, SOITEC; Lars Reger, CEO Germany and CTO, NXP; Frits van Hout, Executive Vice-President and Chief Strategy Officer, ASML; Françoise Chombar, CEO, Melexis; Emmanuel Sabonnadiere, CEO, CEA-Leti; Luc Van den hove, President and CEO, imec; Sabine Nietzsche, Board member, Silicon Saxony and Vice President, GlobalFoundries; Laith Altimime, President, SEMI Europe (coordinator of METIS); Yolande Berbers, President, European Society for Engineering Education (SEFI); James Calleja, President, European Forum for Technical Vocational Education and Training (EFVET); Ludovic Voet, Confederal Secretary, European Trade Union Confederation (ETUC).Emir Demircan is director of Advocacy and Public Policy at SEMI Europe. To learn more about SEMI Europe advocacy, contact Emir at [email protected].

A 500,000 ft2 (~47,000 m2) state-of-the-art cleanroom facility still towers as the largest U.S. high-technology investment in Vietnam 10 years after starting operations in Saigon High Tech Park in District 9, Ho Chi Minh City. The structure built by Intel Products Vietnam (IPV) on the back of a $1 billion investment is the largest assembly and test manufacturing facility (ATM) in the Intel assembly and test network. IPV turns out products that are helping power cutting-edge applications along with the next wave of semiconductor industry growth as it homes in on 5G, Internet of Things (IoT), desktop and mobile. And it has been a boon to the local economy, generating more than 5,000 high-skill jobs across a number of assembly and test disciplines since launching operations in 2010. It has also contributed to over US$37 billion in exports from 2010 to 2019, accounting for over 60% of Saigon High-Tech Park’s annual export values in 2019. With its vision “to create the future of Intel and Vietnam,” Intel continues to be a strong long-term partner in Vietnam. I recently spoke with Kim Huat (KH) Ooi, vice president of Manufacturing and Operations and General Manager at Intel Products Vietnam (IPV), about the facility’s vital role in Intel’s overall manufacturing operations, its support for the E E ecosystem in Ho Chi Minh City, and measures it has implemented to reduce the impact of the COVID-19 pandemic on the facility and protect employees. Ooi leads and manages the site to support Intel’s business in Vietnam. His responsibilities include overseeing factory operations and employee relations; enriching the Intel image and brand; building strategic relationships with communities, media, governments, and local authorities; and working with the industry ecosystem and government. IPV employees celebrate Intel’s 50th anniversary in 2018. Ng: How does IPV campus complement the rest of Intel manufacturing sites and be nearer your customers and supplier base?Ooi: Intel Vietnam is an important part of Intel’s manufacturing presence worldwide. IPV has been operating for nearly 14 years in Vietnam and has celebrated multiple milestones along the way. As a site, we have matured and grown over the years. In March this year, we celebrated a proud milestone – the rollout our 2 billionth unit – that reflects the value of IPV to Intel Corporation as these Made in Vietnam products support its customers worldwide. One of our philosophies is to work with and grow local ecosystems in countries where we operate. In Vietnam, Intel has been offering technical and managerial expertise to many local suppliers in Vietnam to help them expand their business and services to other foreign direct investment (FDI) customers in the industry. Over the past 10 years, Intel’s supplier list has grown 10-fold from 20 in 2010 to about 180 suppliers in 2020.In today’s world of fast-changing consumer preferences and expectations, we need to help drive development of the latest products and technologies to support strong customer demand and new product portfolios such as 5G. To support evolving customer requirements, our workforce frequently upgrades its skills to work on new products and technologies.Intel as a company is also evolving as it transforms from a PC-centric to a data-centric organization, a shift behind the more than US$70 billion in record revenue Intel posted in 2019. Intel’s data-centric business accounted for more than half of that revenue. IPV plays a key role in Intel’s expansion into new market segments.Ng: What are the key differentiating elements (talent, tax, technology, trade, EHS) in Vietnam that have been instrumental in supporting the E E ecosystem in Ho Chi Minh City?Ooi: Vietnam’s stable political environment and increasingly liberalized trade and investment policies are great for businesses. The region’s young, talented workforce is also one of many competitive advantages that enables it to attract foreign investment. Intel’s announcement to invest in Vietnam in 2006 has played a large part in helping put Vietnam on the map of the global IT and semiconductor industry. The news helped attract industry suppliers and service providers, bolstering Vietnam’s economy and creating jobs. The Vietnam government also figured prominently in sparking the boon by establishing the right policies and incentives to attract foreign investment. Since starting operations, we have seen significant improvements in infrastructure such as roads, ports, airports, broadband and power supply. Vietnam’s standing in the global business community is even stronger today after the government successfully combatted the COVID-19 pandemic early on and introduced policies to help businesses restart operations. We expect all these factors to continue to make Vietnam an attractive relocation target for companies around the world. Ho Chi Minh City People’s Committee Vice Chairman Mr. Duong Anh Duc (center) visited Intel Vietnam to tour the state-of-the-art facility. Ng: What measures have you implemented to reduce the impact of the COVID-19 pandemic and protect employees? Ooi: COVID-19 has taken the world by storm and changed the way we work and live in many ways. It has unquestionably pushed the world to build stronger partnerships among individuals, organizations, businesses and communities. Intel’s manufacturing operations have continued to run at full capacity. Since the outbreak emerged, we have strictly followed required Intel safety measures as well as the Vietnam’s health guidelines. We have also implemented a number of other safety initiatives and protocols to ensure our business runs smoothly. We’re doing everything possible to ensure the well-being of our employees and help them better respond to the pandemic.In coordination with our strategic partners, we have been donating thousands of Personal Protective Equipment (PPE) to the Fatherland Front and Department of Health (DoH) since early March. Recently, in partnership with AmCham Vietnam, Intel donated an imported ambulance with built-in essential equipment to the Ho Chi Minh City 115 Emergency Center. Intel has also teamed with Saigon Hi-Tech Park management to donate two ventilators and N95 masks to DoH.Our employees are also helping out by donating to Vietnam’s Coronavirus Donation Matching campaign. We collected US$13,000 from Intel employees and included matching funds from Intel Foundation to support three non-profit organizations (NPOs) – Saigon Children’s Charity, Kidspire Vietnam and Teach for Vietnam. All told, Intel Products Vietnam has donated US$200,000 to COVID-19 relief efforts, demonstrating our long-term commitment to communities where we operate. Intel Products Vietnam teamed with AmCham Vietnam to donate a fully equipped ambulance to Ho Chi Minh City’s 115 Emergency Center, demonstrating IPV’s long-term corporate social responsibility commitment. In early May, Intel unveiled our 2030 Corporate Strategy and goals to accelerate progress against the world’s critical challenges and help drive positive global outcomes. Part of our 2030 goals, our RISE (Responsible, Inclusive, Sustainable, Enabling) strategy focuses on the company’s commitment to its corporate social responsibility (CSR) initiatives to create a more responsible, inclusive, safe and sustainable world through technology and collective action. IPV has also committed to implementing the RISE strategy in Vietnam with local community initiatives and technology interventions. Bee Bee Ng is president of SEMI Southeast Asia.

On 21 September, SEMI and a coalition of 40 industry organisations sent a letter to European Commission President Ursula von der Leyen calling for decisive action to solve implementation issues within the European Union Waste Framework Directive, specifically the Substances of Concern in Products (SCIP) database.The signatories, who represent a very significant part of the European economy, are requesting urgent resolution of implementation issues for the SCIP database, which is designed to support the circular economy as defined in the European Green Deal. The database is required under Article 9.1 of the updated Waste Framework Directive.In the letter, the signatories ask President von der Leyen to take immediate action to: Postpone the SCIP notification deadline of 5 January 2021 to at least one year after finalization of the database; Conduct a study on the usefulness, feasibility, proportionality and impact of the database; Instruct the European Chemicals Agency (ECHA) to adapt the SCIP database according to the outcome of the proposed study. ECHA failed to complete development of the database by the January 2020 deadline required by the Waste Framework Directive, leaving companies insufficient time to develop, test and adapt their own systems to meet the January 2021 SCIP notification deadline.Over the last two years, the signatories have repeatedly shared their serious concerns regarding the viability, proportionality and value of the SCIP database with the European Commission and the ECHA, yet those concerns remain unresolved.Contrary to the EU Better Regulation principles that call for open and transparent decision making, Article 9.1 was added to the revised Waste Framework Directive during the final stage of the co-decision process without any prior stakeholder consultation or impact assessment. A proper impact study should help shape the way forward to deliver on the EU ambition of driving a circular European economy.Coalition PartnersEmir Demircan is director of Advocacy and Public Policy at SEMI Europe.

To attract and cultivate new talent across the microelectronics industry, virtual SEMICON West 2020 offered wide-ranging career insights for engineering students seeking that vital first job and young employees embarking on their careers. They learned about overcoming challenges at work and gained a competitive edge by connecting with industry leaders for insider knowledge. These are just some examples of how the SEMI Foundation and the SEMI Workforce Development and Diversity, Equity and Inclusion (DEI) initiatives serve as a springboard to careers in the industry and help close its talent gap.Following are experiences of aspiring engineers at SEMICON West and career lessons presented to help them shape the future of our semiconductor industry.Jump-Starting Careers at SEMICON West 2020More than 600 students from over 50 colleges and universities across the Unites States joined SEMICON West 2020 to jump-start their careers in the semiconductor industry. With free access to SEMI’s first virtual expo, they connected with recruiters and companies in the exhibit hall, and sponged up insights from speakers about digital internships, job opportunities, and key trends shaping the digital future.“It was almost overwhelming,” said Jason Wong, 20, a junior at San Jose State University working toward an advanced degree in mechanical engineering. “It was kind of like an engineering student’s dream for contacts and knowledge all on one platform.”Wong visited about 15 booths in the online exhibit hall to speak with company representatives about his field of interest – microelectromechanical systems (MEMS).“MEMS is a pretty niche area, so it was really surprising how many companies were there in this category alone,” Wong said.Through the expo’s chat tool, Wong made some solid contacts and has followed up with several engineers via email, LinkedIn and Zoom meetings, cultivating what he believes will be “some long-lasting and valuable connections.”“I’m not really looking for a job at the moment, but I hope to get an internship at some point,” Wong said. “With the current (COVID-19) outbreak, a lot of events with opportunities to interact are no longer available, so this was an enlightening and useful experience for me I plan to attend again.”On the other side of the country in Virginia, Devayani Pawar, 23, found it easy to network at SEMICON West. She especially appreciated the free pass for students and practical sessions in the Smart Workforce Pavilion tailored to help early-career job seekers find opportunities, build contacts, and polish resumes.She was drawn to the Smart Manufacturing Pavilion because of her skills and interests in toolmaking and wafers.“I understand manufacturing and it’s a hot field right now,” said Pawar, who recently earned her master’s degree in data science from George Mason University. “It’s interesting to me how such tiny components can do so much powerful work.”“A lot of people my age aren’t very aware of the microchip industry – they’re mostly focused on information technology and companies like Google, Amazon, or Facebook,” Pawar said.After landing an internship at Micron Technology analyzing wafers and working in clean rooms, she was wowed by the potential of nanotechnology. Pawar learned about the strong demand for data scientists in semiconductor manufacturing. After making connections at SEMICON West and absorbing information, she now has a better handle on career opportunities.“The recruiters and other contacts I made have been so responsive, and now I have a better understanding of use cases and what companies are seeking,” she said.A Day in the Life of an EngineerRight after college in 2017, Erika Gabrielle Hansen joined Applied Materials as an engineer. She told management she wanted to travel, learn about the “big picture” behind the company’s products, and work with customers.In her presentation A Day in the Life of an Engineer at the SEMICON West Smart Workforce Pavilion, she recalled a whirlwind of unforeseen opportunities, soul-searching challenges, and the rewards of personal, professional, and community growth. She also candidly shared lessons learned about pride, collaboration, and resilience.Her journey began when she had the opportunity to share her aspirations for her at career at Applied and landed a dual role as a process engineer and customer account technologist.In her job as a process engineer, Hansen puts her materials engineering degree from Cal Poly, San Luis Obispo to good use analyzing data, solving technical problems, developing new processes to meet customer requirements, and working with cutting-edge technologies. At one moment she might be in a clean-room laboratory wearing a bunny suit doing hands-on work with tools. In another, she could be videoconferencing with hardware, software, and systems engineers worldwide, or preparing a report for upper management.“I was very nervous at first as a process engineer,” Hansen said. “I was the only person in my group who didn’t have a Ph.D. and tried to compensate for that by doing things on my own and not asking for help.”After making a few mistakes, she began to turn to her team for their expertise and sharing the results of her work – both good and bad – with them.“Having humility to ask for help and not let pride get in the way was a huge learning point for me,” she said.As a customer account technologist, she has made a dozen trips to customer sites in four countries to implement new processes or resolve technical issues. By seeing tools in action, she now has what she calls a “whole picture” perspective on their effectiveness, while enjoying the camaraderie of colleagues and sampling local cuisines, sites, and scenes around the world.At one point, she was assigned to lead an international team to resolve an issue with a major customer – her greatest challenge yet and her first time in such a role. She struggled to overcome language barriers and eventually told her boss she might not be the best person to lead the project. He promised to provide more support, and her team went on to resolve the customer’s problem.“I picked myself up, reached out to people with international experience, and changed my communication style,” Hansen said. “I learned it’s okay to be uncomfortable, to flex my leadership style, and be resilient, which is a learned skill.”Building a Better Network: Crucial ConnectionsAndrew Carnegie, one of history’s richest industrialists and most generous philanthropists, said 85 percent of a person’s success is based on “interpersonal relationships” and “abilities to be a human being.” Professional skills account for just 15 percent of success.While advancing to her current role as Chief Marketing Officer for FormFactor, Amy Leong found this advice critical to her career trajectory. Just like the challenge of raising a strong family, building a successful career “takes a village… you can’t do it alone,” she said in her Smart Workforce Pavilion presentation Building a Better Network: Crucial Connections.Outperforming expectations might be essential early in one’s career to get promotions, raises, and the attention, but that mindset goes only so far.“As seniority levels increase, people already know you’re a phenomenal performer and expect nothing less,” Leong said. “So, the higher you go the more vital it is to spend almost a disproportionate amount of effort on building relationships.”Building your network isn’t about the quantity of one’s business cards or LinkedIn connections; it’s about building quality relationships with mutual benefits over the long run.“We need to be smart about return on investment when building our professional network,” she said. “You help me, and I help you. It’s win-win horse trading.”And the most important factor in career success? For Leong, a strong family foundation has mattered most.“Family comes first,” said Leong, who has twin teenagers. “Take care of the ones you love. Check in with your family whenever you can. Family relationships are bound by blood. Thanks to my retired parents and a helpful husband, we tough it through.”She reemphasized the importance of mutually beneficial relationships, noting “A rising tide will lift all boats.”Fostering Talent for the Industry’s FutureDeveloping young talent and future leaders in microelectronics stands as a persistent and growing need – and a critical challenge to realizing expected growth. Emerging technologies such as artificial intelligence, quantum computing, and augmented/virtual reality are expected to impact a huge range of markets, leading to projections that the semiconductor industry will double in size in the next 10 to 15 years.The opportunities for growth and technologies that promise to improve the quality of human life worldwide are breathtaking. The industry’s talent pool will need to scale accordingly, magnifying the importance of expanding industry-wide programs such as the Workforce Development and DEI initiatives that the SEMI Foundation are building. Learn more about how you and your company can get involved with these initiatives on the SEMI Foundation website.Shari Liss is executive director of the SEMI Foundation. She oversees SEMI Workforce Development programs from K-12 through re-skilling for veterans.