European Chips Act

The semiconductor industry is expanding at an unprecedented pace. Global semiconductor revenues are now forecast to exceed $1 trillion annually by 2030, yet recruitment is struggling to keep pace with the demand for new workers. This is why talent development is a critical focus for SEMI and the SEMI Foundation.Young professionals and students are crucial stakeholders of future talent. Held during SEMICON Europa, Building the Talent Pipeline event provided a showcase for some of Europe’s most enthusiastic promoters of careers in the industry: the Student Ambassadors of the European Chip Skills Academy (ECSA). The session opened with Andra Bornea, a Master’s student of electrical engineering at the Technical University of Cluj-Napoca in Romania, who shared the inspiring story of her journey towards a career in electronics. “For me, it started when I attended the ECS Summer School in 2023 along with 39 other students. It was a life-changing experience,” Bornea shared.The Summer School is a week-long programme jointly organised by AENEAS, ECSA, EPoSS and Inside, bringing together lectures, demonstrations and interactive sessions that give students a first-hand glimpse into what a career in semiconductors can look like. For Bornea, the impact was immediate and decisive. “Attending the Summer School convinced me to shift the focus of my studies from telecommunications and pursue a Master’s in electrical engineering,” she added. Today, Bornea is one of 70 students across Europe who form the ECSA Student Ambassador Programme, a community she describes as “a vibrant network of motivated students working towards the goal of keeping Europe at the forefront of the global semiconductor industry.”Andra Bornea, Technical University of Cluj-Napoca The event also featured other ECSA student ambassadors who are actively promoting the semiconductor industry within their own academic communities. One of them was András Bálint Mészáros, an electrical engineering student at the Budapest University of Technology and Economics, who spoke about his determination to build a student electronics club despite facing administrative hurdles along the way. Reflecting on the process, Mészáros said, “ECSA provided good opportunities to start a community of students interested in observing how the microelectronics industry works.”András Mészáros, Budapest University of Technology and Economics A similar spirit of initiative was shared by Nassim Beladel, a Master’s student at ETH Zurich, who described founding Young Neuromorphs which is a student association focused on computational hardware design inspired by the structure of the human brain. Beladel outlined ambitious plans for the group, including an FPGA hackathon in 2026 supported by the Edge AI Foundation, as well as a proposal to present the association’s work at an IEEE event in Shanghai. Nassim Beladel, ETH Zürich These new initiatives supplement a vibrant network of clubs and events around Europe. Octavian-Constantin Axinte, a Master’s student at the Technical University of Cluj-Napoca, told the forum of a Romanian competition for electronics students which has its roots way back in 1992. The Technologies of Interconnections in Electronics (TIE) contest attracted 1,500 students to its final stage in 2025. Axinte said that the benefits of participation included “hands-on experience of professional work, interaction with teachers, and, if all goes well, a job offer!” Octavian Axinte, Technical University of Cluj-Napoca Pioneering Research Efforts of the Next Generation of Students The Building the Talent Pipeline event also gave ECSA student ambassadors an opportunity to describe the findings of research projects that they have undertaken. Laura Sondakh, a Master’s student at Ghent University, presented her research into the environmental and social impacts of tantalum and cobalt which are critical minerals used in electronic components such as capacitors. “These minerals mostly come from the Democratic Republic of Congo, a country which ranks very low on development indices,” she explained, noting that many mines are located in conflict-affected regions in the east of the country. Laura Sondakh, Ghent University Vuk Vulević, a Bachelor’s student of telecommunications and IT at the University of Belgrade, shared his work on the applications of quantum computing, highlighting its potential beyond classic engineering uses such as machine learning. He explained how quantum technologies could also be applied “in pharmacology, for simulating complex molecules and testing compounds virtually, and in finance, for performing risk analyses and Monte Carlo simulations at high speed.” Vuk Vulević, University of Belgrade Z Zainab, a Research Assistant at Hochschule Anhalt, shared insights from her research into how mechanical strain can be introduced during the wafer saw-dicing process which is a critical step in turning wafers into individual chips. Using Raman spectroscopy, her work helps identify how key process parameters influence wafer integrity, enabling manufacturers to better optimise dicing conditions and reduce hidden damage that can affect chip reliability and manufacturing efficiency.Z Zainab, Research Assistant, Hochschule Anhalt Future Plans for Building the Talent Pipeline The event concluded by looking ahead at how SEMI and its partners are scaling up programmes to support talent development worldwide. Victoria Cummings, Senior Manager for Workforce Development and EU Projects at SEMI Europe, introduced Reinforcing Skills in Chips Design for Europe (RESCHIP4EU), a Master’s program for training the next generation of semiconductor designers supported by SEMI Europe and STMicroelectronics. Outlining the project’s ambition, Cummings said, “The program has a broad curriculum, covering everything from silicon chips and SoCs to safety-critical software, how to run a team, and how to start a semiconductor business.” Victoria Cummings, Senior Manager, Workforce Development and EU Projects, SEMI Europe The focus then shifted towards engaging younger learners. Marco van Schagen and Tijl Bouman, co-founders of JuniorIOT, unveiled their newest workshop, Chips in Schools, which builds on their work to spark interest in electronics among younger students. During a hands-on demonstration, audience members of all ages were invited to examine LEDs under a microscope, learning how different chips can be identified and classified by function.The Chips in Schools workshop will soon be available on the ECSA e-learning platform as part of the ongoing collaboration between ECSA and JuniorIOT. Reflecting on the importance of early engagement, van Schagen noted: “When we talk about the talent pipeline, we need to ask where this pipeline really begins. For us, it’s so important that we reach out to children early to foster their sense of curiosity and discovery.”Marco van Schagen, Co-founder of JuniorIOT, demonstrating the Chips in Schools workshop with Victoria Cummings.Rounding off the session, Mike Glavin, Program Director for Workforce Development at the SEMI Foundation, spoke about efforts to significantly scale the foundation’s impact. He described how, despite hundreds of individual microelectronics education initiatives across schools and colleges in the United States, their collective impact has often been limited by fragmentation and a lack of coordinated promotion. To address this, Glavin introduced the National Network for Microelectronics Education (NNME), an initiative designed to unify and amplify existing programmes by connecting educators, students and regional partners. The goal, he explained, is to build scalable, sustainable talent pipelines: “We want to answer the questions, how do we train teachers to educate students about semiconductors? How do we connect to networks through which we can train educators at scale? And how do we develop resources so that a university can host its own semiconductor day, rather than requiring the SEMI Foundation to put it on?” Mike Glavin, Program Director for Workforce Development, SEMI Foundation From university labs to industry-aligned Master’s programs, the message at SEMICON Europa 2025 was clear: talent development is critical to sustaining Europe’s semiconductor ambitions. SEMI would like to thank its partners across academia and industry, as well as the vibrant community of ECSA Student Ambassadors, whose collaboration, commitment and creativity are helping to build a diverse, resilient talent pipeline and shaping the future of the global microelectronics ecosystem.SEMI Contact Jatin Mendiratta, Communications Coordinator, European Projects Email: [email protected]

The GENESIS EU project is reshaping how Europe thinks about semiconductor manufacturing. Its goal is simple but ambitious: reduce usage of harmful chemicals from chip production, cut emissions and waste, and make the industry more circular and resilient.Launched on 1 May 2025, GENESIS – GENerate in Europe a Sustainable Industry for Semiconductor – is a research and innovation project co-funded by the European Union through Chips JU and its participating member states. In addition, Swiss partners are supported by the Swiss State Secretariat for Education, Research and Innovation (SERI).Coordinated by CEA-Leti in Grenoble, GENESIS brings together 58 partners from across the semiconductor value chain: materials and chemistry suppliers, equipment manufacturers, semiconductor fabs, research and technology organisations (RTOs), universities, small and medium-sized enterprises (SMEs), recycling specialists and communication experts. Together, they are working to build a resilient, circular and environmentally responsible microelectronics sector aligned with the European Green Deal and the European Chips Act.Mission and VisionGENESIS exists to future-proof the European semiconductor industry. The project focuses on:Eliminating or replacing per- and polyfluoroalkyl substances (PFAS) and other hazardous substances used in manufacturing processes;Reducing waste and greenhouse gas emissions throughout the production chain;Securing access to critical materials through smarter use, reuse and circular strategies;Deploying advanced monitoring and sensing solutions for gas and liquid environments in fabs.Six Work Packages, One Integrated ApproachTo reach its objectives, GENESIS is structured into six work packages.Work Package 1 – Management, Specifications, and MethodsLead: CEA-LetiWP1 keeps the project on track. It manages the technical, administrative and financial coordination of GENESIS and defines common specifications and methodologies. This includes setting technical recommendations and carrying out environmental impact assessments so that shared targets and consistent methods guide all subsequent work.Work Package 2 – Process, Monitoring Sensing Hardware and SolutionLead: CSEMWP2 develops real-time monitoring technologies capable of detecting and quantifying emissions from process gases such as NF₃, CF₄ or SF₆. By improving transparency and enabling process feedback, GENESIS contributes to the transition toward low-emission semiconductor fabs aligned with EU climate goals.Work Package 3 – Environmentally Friendly Materials AlternativesLead: imecWith global PFAS restrictions tightening, the semiconductor sector urgently needs high-performance, safe alternatives. GENESIS in WP3, is designing and qualifying materials for key manufacturing steps including lithography, etching, cleaning, deposition, and packaging, that reduce industry dependence on PFAS and higher GWP gases while ensuring compatibility with industry performance requirements.Work Package 4 – Minimisation of Waste and EmissionsLead: FraunhoferWP4 addresses the complexity of semiconductor waste streams and explores innovations to enhance abatement efficiency. GENESIS develops recycling, recovery, and closed-loop solutions for gases, slurries, and solvents, with the aim of significantly reducing waste across fabs.Work Package 5 – Materials Scarcity Impact MitigationLead: Università degli Studi di Roma Tor VergataEurope’s dependence on critical raw materials—including gallium, indium, and rare earth elements—represents both an environmental and strategic challenge. GENESIS in WP5 focuses on reducing CRM usage through process innovation and strengthening circularity to enhance supply chain resilience.Work Package 6 – Regulations, Dissemination, Communication and ExploitationLead: SEMI EuropeWP 6 is dedicated to ensuring that GENESIS creates meaningful and lasting impact beyond its technical achievements. It integrates regulatory monitoring, dissemination, communication, and exploitation activities to connect the project’s innovations with industry needs, European policy developments, and wider society. WP6 is coordinated by SEMI Europe, supported by expert partners across the consortium, and serves as the bridge between GENESIS’s scientific work and its real-world influence.Long-term strategyGENESIS is built with one goal in mind: making sure the work happening inside the project translates into real change across Europe’s semiconductor ecosystem. To support this, the project focuses on four key impact areas that help move ideas from research into industry, policy and long-term community engagement.Helping Industry Put Results to WorkA core part of GENESIS is understanding how each partner can use the project’s results in their own environment. Whether it’s new materials, smarter monitoring solutions or better waste-reduction approaches, partners define clear pathways for adoption so GENESIS innovations can move naturally into real industrial use.Staying Connected to Europe’s Policy AgendaSustainability and chemical regulations in Europe are evolving fast, and GENESIS stays close to these developments. The project brings technical insights to discussions around the Green Deal, PFAS regulation, and critical raw materials. This makes sure GENESIS is not only aligned with policy trends, but also contributes to shaping them.Making Knowledge Accessible and Future-FocusedOpen access is an essential part of GENESIS. The project shares its research outputs publicly and supports the creation of educational material for universities and training programmes. This helps the next generation of engineers and specialists build on GENESIS knowledge and carry it forward.Keeping GENESIS Visible and RelevantGENESIS maintains a strong presence across events, conferences, publications and expert discussions. This ongoing engagement ensures that project results remain visible, understood and connected to wider conversations on sustainable semiconductor manufacturing—helping extend the project’s influence well beyond its duration.Towards a Sustainable Semiconductor FutureGENESIS shows that high-performance chips and environmental responsibility can coexist. By uniting materials science, process engineering, monitoring technologies, environmental assessment and policy insight, GENESIS is helping define what responsible, future-ready semiconductor manufacturing will look like tomorrow.Jatin Mendiratta, Communications CoordinatorSEMI Europe Phone: +49 160 402 8899Email: [email protected]

The CxO Summit at SEMICON Europa 2025 spotlighted Europe’s ongoing efforts to build a resilient and globally competitive semiconductor industry, while calling for greater ambition, speed, and unity in execution. Following global disruptions with the automotive supply chain crisis, the European Union launched a continent-wide strategy through the EU Chips Act. While the Act has already spurred significant developments, including construction of the new ESMC fab in Dresden, Europe remains far from its goal of achieving a 20% share of global semiconductor production by 2030. The CxO Summit, part of the SEMICON Europa event in Munich, provided an opportunity for industry leaders to share ideas about how to catalyze the next phase of the European industry’s growth.Ajit Manocha, President and CEO of SEMI opened the summit by describing today’s industry landscape with one word: “unprecedented.” Manocha said, “The global growth of the industry is unprecedented, with 107 new fabs set to come online by 2028, but the uncertainties are unprecedented, from geopolitics to the talent shortage to environmental concerns. So we need unprecedented solutions.” Ajit Manocha, President and CEO, SEMILaith Altimime, President of SEMI Europe echoed the mood of uncertainty, describing Europe as caught “in a perfect storm.” Altimime said, “As we face a combination of internal challenges and intensifying external competition, collaboration is not optional — it is mission critical.” Laith Altimime, President, SEMI EuropePierre Chastenet, Head of the Unit for Microelectronics and Photonics, European Commission, highlighted the tangible progress made under the EU Chips Act. “We now have a proper toolbox to handle a future crisis in the supply chain. The Chips for Europe initiative has led to the creation of five pilot lines for advanced technologies such as FD-SOI and wide bandgap semiconductors.” Chastenet added, “Europe must now capitalize on its strengths, from materials and equipment to design tools and cutting-edge research emerging from our RTOs.”Pierre Chastanet, Head of the Unit for Microelectronics and Photonics, European CommissionEchoing the call for action, Oliver Schenk, Member of the European Parliament, urged stronger regional unity. “Europe must act together, act faster, and act with much bigger ambition,” Schenk said, reinforcing the need for cross-border commitment to strengthen the continent’s semiconductor position.Oliver Schenk, Member of the European Parliament, European ParliamentHighlighting Europe’s most critical technology gap, Luc Van den hove, President and CEO of imec, unveiled plans for a new advanced fab backed by €2.5 billion in investment from the EU, the Flemish government, and ASML. Van den hove urged Europe to commit wholeheartedly to advanced technologies: “We must be more ambitious, and focus on disruptive breakthroughs rather than incremental change if we want to ensure a prosperous future.”Luc Van den hove, President CEO, imecAt the CxO Summit, CEA-Leti and ASML signed a memorandum of understanding (MoU) to deepen their collaboration and accelerate innovation in mainstream semiconductor technologies. Building on promising results in hybrid bonding, the partnership will now target 'More-than-Moore' innovations, including heterogeneous integration and novel substrates like SiC and GaN. “We aim to combine ASML’s world-class lithography expertise with CEA-Leti’s system-level innovation,” said Sébastien Dauvé, CEO of CEA-Leti. The collaboration is set to strengthen Europe’s ecosystem by shortening the path from early research to industrial impact.Left: Anne Hidma, Senior Vice President EUR US, ASML; Right: Sébastien Dauvé, CEO, CEA-LetiTurning to Europe’s industrial base, Christian Senger, CEO of Volkswagen Autonomous Mobility, emphasized the need to shift from risk-aversion to opportunity. While the region’s automotive sector faces intense global competition, particularly from China, Senger highlighted that Europe has the potential to lead in new mobility markets. “The market for autonomous roboshuttles for people transport in large cities is forecast to be worth €400 billion in the US and Europe alone,” he said. With American firms like Waymo and Uber leading the robotaxi space, Senger stressed that Europe must “act swiftly to create an environment that supports an autonomous mobility industry here.”Christian Senger, Member of the Board for Fully Autonomous Mobility and Transport CEO of ADMT GmbH, VolkswagenEurope’s Potential to Create Advanced TechnologyOne of these RTOs, CEA-Leti, is responsible for the FAMES pilot line for FD-SOI technology. Sébastien Dauvé, CEO of CEA-Leti, agreed with Pierre Chastenet that the pilot lines show great promise. He said, “FD-SOI is a big trend in semiconductors, because it enables very low power consumption in embedded devices. We think that adoption of the technology will grow in the coming years, and that is good, because most of the technology is produced in Europe.”Sébastien Dauvé, CEO, CEA-LetiEurope is also widely recognized to be the leading global voice on sustainability – a huge issue of concern to the semiconductor industry. Henri Berthe, President of the Semiconductor and Battery Segment at Scheider Electric, told the summit that 500 million tonnes of CO2 emissions per year are attributable to the semiconductor industry – “more than the whole of Mexico emits!” he said. “We need to make fabs more efficient, and that is why Schneider Electric has launched a new playbook with Applied Materials for sustainable energy abundance for the industry.”Henri Berthe, President of the Semiconductor Segment, Schneider ElectricAnother aspect of Europe’s playbook is support for new fabs. The flagship is ESMC, the joint venture between TSMC, NXP Semiconductors, Bosch, and Infineon. Christian Koitzsch, president and managing director of ESMC, reported to the summit that the project to build in Dresden a 12nm FinFET foundry and a 28nm CMOS line, requiring a total investment of €10bn, is on schedule. “We are now developing local supply chains, hosting a series of ESMC Supplier Days which are open not only to German but generally to European suppliers,” said Koitzsch.Christian Koitzsch, President and Managing Director, European Semiconductor Manufacturing Company (ESMC)As Manfred Horstmann, General Manager and Senior Vice President of Global Foundries, pointed out, the building of the ESMC fab means that Dresden is established as the center of a cluster of semiconductor industry companies. “Global Foundries has its Fab 1 and a mask center in Dresden. In fact, one-third of the chips produced throughout the whole of Europe now comes from Dresden.”Manfred Horstmann, General Manager and Senior Vice President, GlobalFoundriesAn example of ambition was given by Terence Gan, Executive Director of the Institute of Microelectronics of Singapore. Gan told the summit how Singapore has used pilot lines to stimulate research and development in new technologies. He said: “We started research into advanced packaging as long ago as 2011. Most people thought we were mad! But today, there is strong demand for our advanced packaging capabilities because of the rise of AI and its need for high-performance computing.”Terence Gan, Executive Director, Institute of MicroelectronicsBreaking Barriers to ProgressDespite momentum, bureaucratic inefficiencies continue to hamper progress. Narjiss Haddaoui, Managing Director of European Economics called for faster decision-making: “In global competition, speed is a decisive factor. To act fast enough, the EU must change its ‘software’ - the processes by which it considers and makes decisions.” Narjiss Haddaoui, Managing Director, European economicsThe stifling character of European bureaucracy is reflected in the region’s approach to building fabs. Herbert Blaschitz, Executive Vice President of Advanced Technology Facilities at Exyte, compared fab construction timelines: 20 months in Taiwan, 34 in Europe, and 38 in the U.S., attributing delays in Europe to paperwork bottlenecks.Herbert Blaschitz, Executive VP of Advanced Technology Facilities, ExyteFabio Gualandris, President for Quality, Manufacturing and Technology at STMicroelectronics raised another concern — 100% of raw materials used in European fabs come from outside the region. Christophe Frey, Vice-President for EU Engagements at Arm France, added that geopolitical tensions are clouding the path forward: “We are a bit lost in the smoke from the big fire in the world’s semiconductor industry.” Fabio Gualandris, President Quality, Manufacturing Technology, STMicroelectronics Christophe Frey, Vice-President of EU Engagements, Arm FrancePlaybooks For Future SuccessSo amid the uncertainty and global tension, what lessons can the industry learn from successful regional examples? Tuomas Korpela, Business Development Senior Manager at Nokia, credited Finland’s strategic procurement and policy tools with enabling a vibrant semiconductor ecosystem: “Finland creates demand for advanced chips using industrial policy tools, alongside strategic procurement in sectors such as defense and aerospace, and connectivity.” Tuomas Korpela, Business Development Senior Manager - Corporate Development Organization, NokiaAt a regional level, Joerg Schulze, Director of the Bavarian Chips Alliance, said that his organization was supported by the Bavarian State Ministry of Economic Affairs, as well as by companies and universities. “We help semiconductor companies to establish themselves and grow here through help with site searches, networking and contacts, funding and support, and talent acquisition,” said Schulze.Joerg Schulze, Spokesperson for the Bavarian Chips Alliance, Director of the Fraunhofer IISB, Bayern Innovativ GmbHCompanies in the European semiconductor supply chain also provided the summit with their insights into the roots of global success. André Grede, Chief Technology Officer of Comet, described how his company’s strategy is not to wait for customers to tell it what they need, but to be “ahead of the curve.” Grede said: “Is staying in sync with the customer enough? Not for us - we are deeply embedded with our customers, and constantly looking to broaden our relevance to them.”André Grede, CTO, CometChristophe Maleville, Chief Technology Officer of Soitec, provided a real-world example of how this is done. He said: “Our engineered substrates using RF-SOI technology reduce the drain on a mobile phone’s battery power, and cut our customers’ board footprint thanks to RF front end integration. As a result, our products are now in 100% of 5G smartphones.”Christophe Maleville, CTO, SoitecAnne Hidma, Senior Vice-President for Europe and the US at ASML, shared the company’s success formula: “The reasons for ASML’s success include customer focus – decide which markets you are going to be in, and which you are not. We are also all-in on innovation. We nurture an ecosystem, which for us includes imec and CEA-Leti, as well as partnerships with academia. And lastly, we have a strong supply base, which is a core strength of Europe.” In a time marked by both uncertainty and opportunity, the example of ASML shows how the European semiconductor supply chain can survive and thrive.Anne Hidma, Senior Vice President EUR US, ASMLEurope’s Path ForwardThe CxO Summit made one thing clear: Europe has world-class innovation, policy momentum, and industrial commitment. What’s needed now is faster execution, deeper collaboration, and the courage to invest in the technologies of tomorrow. As the industry heads toward the $1 trillion milestone, the decisions made today will shape Europe’s place in the semiconductor world for decades to come.On behalf of SEMI, the SEMI Europe team would like to express appreciation to the industry leaders for sharing their visions and readiness to collaborate during the CxO Summit.SEMI ContactLaith Altimime, President SEMI [email protected]

New pilot lines offer European innovators access to the most advanced semiconductor technologies for product development and validation.The global semiconductor landscape has undergone significant transformation in recent years. With disruptions such as the semiconductor supply chain crisis and the challenges it posed to the automotive sector, Europe’s dependence on external fabrication facilities, particularly in Taiwan, has become a pressing concern. In response, the European Union (EU) introduced the EU Chips Act, a comprehensive framework designed to reduce this reliance and boost Europe’s share of the global semiconductor market. ITF Chip into the Future, hosted by imec at SEMICON Europa 2024, was a pivotal event that brought together industry leaders, policymakers, and experts to explore the implementation of the EU Chips Act and the future of Europe’s semiconductor ecosystem. Jari Kinaret, Executive Director of the Chips Joint Undertaking (Chips JU)—the body overseeing the EU’s semiconductor investments—explained, “The Chips JU is about capacity building to drive semiconductor innovation in Europe. We will continue to be dependent on the rest of the world, but we want to make sure that the rest of the world depends on us as well.” Jari Kinaret, Executive Director, Chips JUEuropean research is driving progress towards sub-nanometer fabricationOne of the pilot lines, located at imec’s research center in Belgium, is focused on advancing methods that push Moore’s Law forward by achieving smaller and more efficient circuit features. As Luc Van den hove, President and CEO of imec, explained, “imec is now powering innovation for tomorrow’s chip designs, including stacked layers of chips, with each layer containing specific functionality implemented on chip processes optimized for each function. This allows us to scale much further than if all functionality had to be implemented on a single monolithic layer.”Luc Van den hove, President and CEO, imec Another pilot line, based in France and operated by CEA-Leti, is focused on pushing the limits of technology across multiple dimensions. CEA-Leti CEO, Sébastien Dauvé, explained that the goal of the FAMES pilot line is to advance “not only FD-SOI at 10nm and 7nm nodes, but also novel non-volatile memory technologies, RF components, 3D integration, and the development of small inductors for DC-DC converters.” Sébastien Dauvé, CEO, CEA-LetiAdvancements in 3D integration and chiplet technologies are closely tied to innovation in chip packaging. Christoph Kutter, Executive Director of Fraunhofer EMS, described how the Advanced Packaging and Heterogeneous Integration for Electronic Components and Systems (APECS) pilot line in Germany is designed to meet the needs of industrial customers’ growing demand for advanced packaging solutions. Kutter noted “Customers told us that they needed to integrate logic and power, sensors and logic, and other combinations of functions. We have built the APECS pilot line to provide what they asked for.”Christoph Kutter, Executive Director, Fraunhofer EMSThe EU Chips Act is spurring investments not only in chip fabrication but also in the underlying technologies which support chipmaking. Emmanuel Sabonnadière, EVP at Soitec, highlighted how fabrication of advanced silicon carbide (SiC) power devices “is enabled by SmartSiC™ technology from Soitec – part of a built-in-Europe solution for silicon carbide.” Sabonnadière explained that SmartSiC technology “creates very thin layers of SiC material which make really differentiated substrates supporting the production of high-performance SiC devices.” Emmanuel Sabonnadière, EVP, SoitecInnovation in materials emerged as an important theme at ITF Chip into the Future. Julien Arcamone, Vice President of Corporate R D at ASM, described the critical role of materials for atomic layer deposition (ALD) in the advancing 3D semiconductor integration. Arcamone emphasized the importance of collaboration across the semiconductor value chain, describing ASM’s partnership with imec as part of “a win-win ecosystem.” Julien Arcamone, Vice President of Corporate R D, ASMDeveloping the skills to implement advanced semiconductor technologiesWhile the EU Chips Act is subsidizing the construction of new facilities including pilot lines needed for the hardware of the semiconductor industry’s expansion – the ITF speakers underlined the equally important “software” element of the semiconductor industry ecosystem: the knowledge and expertise of the people working in the industry. One of the biggest challenges in implementing the EU Chips Act is addressing Europe’s talent gap. Katrien Marent, Executive Vice President and Chief Marketing and Communications Officer at imec, said that the gap is in part “because students who graduate in STEM subjects are not trained in advanced semiconductor technologies.” From left to right: Katrien Marent, Executive Vice President and Chief Marketing and Communications Officer, imec; Julien Arcamone, Vice President of Corporate R D, ASM; Thomas Heurung, CEO, Siemens EDA; Frédérique Le Grevès, President STMicroelectronics France and Executive Vice President, Europe France Public Affairs, STMicroelectronics; Romano Hoofman, Director imec.IC-link, imec; and Christophe Frey, Vice-President of EU engagements Managing Director, ARM.Thomas Heurung, CEO of Siemens EDA, highlighted the need for educational reform in the electronics industry. He suggested that “we might not have the right degree-level curriculum for changing times in the electronics industry. We need to change the way that we train students at university, and we need more scope for early or mid-career training on specialist micro-curriculums aimed at a particular skill or knowledge set.”The industry also struggles to attract individuals. Frédérique Le Grevès, President of STMicroelectronics France and Executive Vice President, Europe France Public Affairs of STMicroelectronics, emphasizes the importance of rebranding the industry to attract new talent. She remarked, “The word ‘semiconductor’ itself isn't very exciting—it’s even off-putting to some. By simply changing the name of educational programs, we’ve seen significant increases in enrollment. This demonstrates the power of language in shaping perceptions and interest.”Thomas Heurung of Siemens EDA also called for a stronger emphasis on entrepreneurship, noting “there is a big contrast between Europe and the US, particularly Silicon Valley.” He explained how his company’s Cre8Ventures unit had been set up to help start-ups through the key stages of creating a successful new company, including product development, attracting funding, and bringing the product to market. Thomas Fleischmann, Program Manager at Robert Bosch, explained how the EU Chips Act has accelerated the formation of the European Semiconductor Manufacturing Company (ESMC) joint venture, in which Bosch is a key stakeholder. ESMC is building a new semiconductor fabrication plant in Dresden, dedicated to producing chips for the automotive and industrial sectors. Fleischmann emphasized that ESMC will play a crucial role in helping Europe “scale advanced technologies to high volumes at a competitive cost.”In addition, the EU Chips Act also provides a broader platform for the expansion of Europe’s deep tech capacity. This includes the creation of five pilot lines, which will offer European companies access to manufacturing capacity for prototyping at the most advanced semiconductor technology nodes.Thomas Fleischmann, Program Manager, Robert BoschITF Chip into the Future at SEMICON Europa 2024 highlighted the broad scope of the EU Chips Act – not only supporting the building of advanced fabs but also providing the foundations for technology development, production, and marketing – all aimed at supporting semiconductor innovation in Europe. SEMI ContactMaria Daniela Perez, Communications ManagerEmail: [email protected]

Leaders in the semiconductor industry are finding ways to balance rapid demand growth with strategies to mitigate the risks of geopolitical uncertainty and a complex supply chain.At the CxO Summit during SEMICON Europa, industry leaders gathered to share insights into the immense opportunities ahead for the semiconductor sector, as well as the challenges that could impede growth. Laith Altimime, President of SEMI Europe, highlighted how discussions last year centered on reaching $1 trillion in global sales by 2030. “The conversation today is about how far above $1 trillion we will be in 2030,” said Altimime. “Artificial intelligence is an amazing and exciting technology, and the semiconductor industry is at the heart of it.”Laith Altimime, President, SEMI EuropeAjit Manocha, President and CEO of SEMI, described the current state of the semiconductor industry with one word – “unprecedented.” Emphasizing quantum computing as the next growth driver after AI, Manocha urged leaders to prepare for the next landmark - $4 trillion in global sales by 2040. However, the challenges facing the industry are equally unprecedented. Manocha identified four key obstacles: geopolitical volatility, the Net Zero challenge, the competition for top talent, and supply chain disruptions. “We need to work together to solve these challenges – we need unprecedented collaboration,” he explained. Ajit Manocha, President and CEO, SEMIA European Perspective on the Industry’s ChallengesWith the CHIPS Act in the US and the European Union (EU) Chips Act, the industry is also seeing unprecedented governmental engagement. Gustav Kolbe, Acting Director of Enabling and Emerging Technologies at Directorate-General for Communications Networks, Content and Technology of the European Commission, explained that Europe had been deeply impacted by the effect of trade tensions and supply chain disruptions. “In the field of semiconductors, we realized that we cannot keep doing business as usual and expect to achieve more resilience and reduced dependence on non-European supply chains,” Kolbe said. Gustav Kolbe, Acting Director of Enabling and Emerging Technologies, DG CONNECT, European CommissionJari Kinaret, Executive Director of the Chips Joint Undertaking (Chips JU), which is responsible for implementing EU Chips Act programs, described how its projects amplify the effect of EU funding by leveraging matching contributions from member states and participating companies. “This means that our budget of €4 billion actually produces investments in the semiconductor industry of about €11 billion,” he noted. Jari Kinaret, Executive Director, Chips JUThe Chips JU funded projects are designed to position Europe at the forefront of advanced semiconductor technology. Belgium’s imec, for example, is operating a Chips JU pilot line focused on leading-edge semiconductor innovation. Luc Van den hove, President and CEO of imec, highlighted the potential for 3D integration, “We can now combine multiple chips through silicon interposers with very fast connectivity between them. This allows us to build compute platforms which are far larger than what can be made with a single silicon chip,” he explained referring to this approach as “CMOS 2.0.” However, Van den hove warned that Europe cannot achieve its goals alone, emphasizing the complex semiconductor value chain and the need for collaboration. “Self-sufficiency leads to mediocrity,” he warned, advocating for a global approach that leverages the “best of the best.”Luc Van den hove, President and CEO, imecStephan Haferl, Chief Executive Officer of Comet Group, introduced the CA20, a tool designed to improve efficiency and quality in semiconductor manufacturing. The CA20 uses advanced imaging and AI to quickly identify and address production challenges, such as defects in solder bumps, without damaging components. Now fully automated, it integrates smoothly into factory workflows, providing real-time information to help manufacturers maintain high standards and increase production yields. This innovation highlights the role of new technologies in overcoming key obstacles and driving progress in the semiconductor industry.Left to right: Isabella Drolz, Vice President Marketing Product Strategy, Comet Yxlon; Laith Altimime, President, SEMI Europe; Stephan Haferl, Chief Executive Officer, Comet Group; and Dionys van de Ven, President, Comet YxlonCarlos Mazure, Chief Strategy Officer at Institute of Microelectronics – A*STAR in Singapore, illustrated this point by highlighting the institute’s focus on advanced packaging, a key Singaporean strength. “We have built a state-of-the-art 300mm prototyping line, enabling companies to implement wafer-to-wafer and chip-to-wafer bonding as well as fanout chip packaging,” Mazure said. Carlos Mazure, Chief Strategy Officer, Institute of Microelectronics – A*STARTurning back to Europe, Pierre Barnabé, CEO of Soitec, highlighted materials science as a regional strength. Soitec’s engineered substrates are driving energy efficiency breakthroughs in electronic, acoustic, and photonic applications. “We can bond anything to anything, creating advanced substrates for any active layer,” Barnabé explained. Pierre Barnabé, CEO, SoitecKai Beckmann, Member of the Executive Board and CEO Electronics at Merck KGaA, Darmstadt, Germany, also emphasized the role of materials in enabling sustainable growth. “The semiconductor industry faces a challenge with the contribution of process gases to its total greenhouse gas emissions. We hope to solve the problem by using AI to support materials research, and to design new molecules – an approach we have learned from the pharmaceuticals industry,” Beckmann shared. Kai Beckmann, Member of the Executive Board and CEO Electronics, Merck KGaA, Darmstadt, GermanyCollaboration Strengthens the Semiconductor Supply Chain Despite the breadth of enabling technologies emerging from Europe, the rapid growth in semiconductor demand has not always been matched by a secure supply. Barbara Frenkel, Member of the Executive Board Purchase at Porsche, shared that the company is collaborating with the industry to improve its access to the chips needed for automotive electrification. This includes joining industry groups such as the SEMI Global Automotive Advisory Council (GAAC) and, as she said, “learning your language.” Frenkel added, “Porsche aims to emulate Apple’s approach with Intel and Motorola to drive innovation – we will do the same with suppliers of automotive chips.”Barbara Frenkel, Member of the Executive Board Purchase, PorscheAnother solution to supply constraints is to widen the supply pipeline. John Behnke, General Manager for Smart Manufacturing at Inficon, described how smart technology can significantly improve efficiency and output. “A semiconductor fab is 100 times more complicated than anything else in the world – it is a mathematical nightmare to model it. That gives massive opportunities for improved productivity if we can implement smart control technologies,” Behnke explained. John Behnke, General Manager for Smart Manufacturing, InficonThe Challenge of Achieving Sustainable GrowthWhile the prospect of exceeding $1 trillion in annual sales energizes the industry, there is widespread recognition that growth must not come at the expense of environmental responsibility. As the industry doubles in size in the 2020s, it cannot afford to double its use of resources, such as energy or greenhouse gas emissions. Frédéric Godemel, Executive Vice President for Power Systems and Services at Schneider Electric, shared that the biggest impact on sustainability could come from “energy frugality” – using energy more efficiently. He explained that implementing data fusion in a semiconductor fab – combining detailed analysis of the operation of chillers with external data sets, such as weather conditions to allow for more efficient use – results in energy savings of 10%. “This approach saved costs, reduced CO2 emissions, and provided a financial payback in less than one year,” Godemel said.Frédéric Godemel, Executive Vice President for Power Systems and Services, Schneider ElectricThe value of smart control in fab operations was also highlighted by Katharina Westrich, Global Vice President of Electronics, Semiconductors Simulation Digital Industries at Siemens. She described how Siemens makes digital twins of factories before they are built. “This is an approach that the semiconductor industry can also adopt,” Westrich said. “A digital twin enables more efficient allocation of resources to the fab and sub-fab, allowing simulation of fab operation and optimization of processes and resources.”Katharina Westrich, Global Vice President of Electronics, Semiconductors Simulation Digital Industries, SiemensThe semiconductor industry faces a future full of opportunity, yet also marked by significant obstacles—ones that delegates at the CxO Summit are now better equipped to tackle head-on.On behalf of SEMI, the SEMI Europe team would like to express appreciation to the industry leaders for sharing their visions and readiness to collaborate during the CxO Summit.SEMI ContactCassandra Melvin, Senior Director of Business Development and OperationsEmail: [email protected]

In the rapidly-evolving semiconductor industry, maintaining a competitive edge is crucial. To position Europe at the forefront of global semiconductor innovation, imec is leading the NanoIC pilot line initiative. Aligned with the European Chips Act, this initiative is a strategic move to bolster Europe's leadership in key markets like high performance computing, automotive, and healthcare.SEMI spoke with Srikanth Samavedam and Jo De Boeck from imec, Belgium, to learn more about the NanoIC pilot line and to better understand its goals, challenges, and prospects. From transitioning to gate-all-around (GAA) nanosheet devices, to developing advanced memory technologies and interconnects, this conversation highlights the cutting-edge advancements made possible through collaboration across the industry’s value chain.SEMI: How is the NanoIC pilot line working to revolutionize the semiconductor industry, and what are its main objectives?Samavedam: The NanoIC pilot line is a European initiative aimed at bridging the gap between R D and industrial innovation. The project is creating a beyond-2nm system-on-chip (SoC) pilot line, developing advanced logic, memory, and interconnect technologies. This effort supports the European Chips Act's vision for leadership and competitiveness in global semiconductor innovation, particularly in critical markets like high performance computing, communication, automotive, energy, and healthcare. However, advanced technologies come with more complexity, and addressing these complexity challenges requires more mature module baseline flows. By improving baseline flow repeatability and variability while reducing defectivity, we can accelerate the development of future technologies. The NanoIC pilot line is working to provide access to these advanced technologies and baselines to develop future compute systems. This will help ensure European competitiveness across the industry – from semiconductor materials, equipment and design to systems and applications.SEMI: Who are the core partners involved in this initiative?De Boeck: Key partners of the pilot line include CEA-Leti, Fraunhofer-Gesellschaft, VTT Technical Research Centre of Finland, Tyndall National Institute, and the Center for Surface Science and Nanotechnology of the University POLITEHNICA of Bucharest. This project is also supported by the Flemish government, other participating states, and the Chips Joint Undertaking of the EU Chips Act.These institutions and organizations bring a wealth of knowledge and resources, and imec compliments their efforts by providing access to its global partnerships with key industry leaders. The NanoIC pilot line is helping strengthen Europe’s global semiconductor industry leadership while aligning efforts with other regional Chips Acts. SEMI: Can you elaborate on the significance of transitioning from field-effect transistors (FinFETs) transistors to GAA nanosheet devices in CMOS technology?Samavedam: The transition from FinFETs to GAA nanosheet devices is a significant advancement in CMOS device technology. FinFETs have been the backbone of CMOS technology from the 22nm to the 3nm node. But starting at the 2nm node, nanosheet devices will need to be introduced. Nanosheet devices, including variants like Forksheet devices, are expected to drive scaling and performance through three generations – 2nm, A14, and A10. Complementary FET (CFET) architectures are also expected to be introduced around 2031 at the A7 node, which will represent another major inflection point in CMOS device design. This progression requires extensive research into new materials, process modules, equipment, and advanced patterning capabilities using high numerical aperture extreme ultraviolet (high NA EUV) lithography – all of which will be implemented on the NanoIC pilot line. FIGURE PROVIDED BY IMEC │ SCHEMATIC ILLUSTRATION OF A FUTURE COMPUTE SYSTEM. THE SYSTEM IS MADE OF LARGE MULTI-DIE ELECTRICAL-OPTICAL INTERPOSER PROVIDING ELECTRICAL AND OPTICAL INTERCONNECTS BETWEEN THE VARIOUS CHIPLETS (CPUS, GPUS, HBM). ALSO SHOWN ARE CONNECTIONS TO PACKAGE SUBSTRATE, AS WELL AS FIBER CONNECTORS AND AN INTEGRATED LASER SOURCE. CENTRAL PROCESSING UNIT (CPU); GRAPHICS PROCESSING UNIT (GPU); HIGH BANDWITH MEMORY (HBM); PROCESSING UNIT THAT CAN INCLUDE CPUS, GPUS, AND OTHER SPECIALIZED PROCESSORS (XPU); APPLICATION-SPECIFIC INTEGRATED CIRCUIT (ASIC); ELECTRONIC INTEGRATED CIRCUIT (EIC); FF-LEVEL: FEMTOFARAD-LEVEL; FIELD-PROGRAMMABLE GATE ARRAY (FGPA); GAAS QD: GALLIUM ARSENIDE QUANTUM DOT; INTEGRATED SILICON PHOTONICS PLATFORM 300MM (ISIPP300); REDISTRIBUTION LAYER (RDL); SILICON PHOTONICS (SIPHO); THROUGH PACKAGE VIA (TPV). SEMI: What are the key innovations necessary for advancing memory technology?Samavedam: As SRAM scaling slows, the exploration of novel, dense embedded memory concepts will become imperative. Technologies like spin orbit torque magnetic RAM (SOT-MRAM) and 2-transistor 0-capacitor (2T0C) embedded DRAM using deposited semiconductors like indium gallium zinc oxide (IGZO) are promising. These innovations address memory capacity and bandwidth challenges from new workloads in compute systems. Additionally, developing a 3D memory platform to explore future memory options will be essential for improving SRAM and DRAM. These advancements will help meet the demands of new applications like machine learning, augmented and virtual reality, and autonomous vehicles.SEMI: How do advanced interconnect technologies contribute to the future of semiconductor design?Samavedam: Advanced interconnect technologies, like chip-to-chip lateral (2.5D or interposer technologies) and vertical interconnects (3D technologies), play a crucial role in addressing memory capacity and bandwidth challenges. These technologies enable the partitioning of SoC functions into separate dies, allowing for more efficient and scalable designs. Advances like pitch scaling of micro-bumps and copper (Cu) hybrid bonding are facilitating this fine-grained partitioning of SoC functions. Additionally, optical interconnects and 3D interconnect-enabled co-packaging provide high-bandwidth and low-power connectivity at wafer scale. The rise of chiplet architectures and standardization will also increase the demand for low-cost, tight-pitch interconnect technologies like Cu/polymer redistribution layers.SEMI: How do your collaborators benefit from the NanoIC pilot line? De Boeck: One of the biggest collaborator benefits is the pilot line’s commitment to knowledge sharing through R D access and training. We invite foundries, IDMs, materials suppliers, equipment suppliers, and system companies/OEMs to jointly develop the materials, process modules, and integration flows to accelerate the development of beyond-2nm SoC technology pillars.Design pathfinding and system exploration process design kits (PDKs) will be available for start-ups, small- and medium enterprises, universities, and design and system companies to aid in prototyping and testing their designs. The NanoIC pilot line will also offer comprehensive training programs, including virtual PDK training, bootcamps for faculty, and internships and expert courses for students. To learn more, experts and key partners of the NanoIC pilot line will be presenting from 14 -16:40 at SEMICON Europa on November 12. imec’s program, ITF Chip into the Future, will highlight advancements in digital technology, capacity building through the European Chips Act, and the role of the NanoIC pilot line in accelerating beyond-2nm innovation. The conversation will also address industry requirements for pilot lines, emerging initiatives boosting Europe’s innovation and competitiveness, and perspectives on advanced materials and semiconductor equipment. Srikanth Samavedam, Senior Vice President of Semiconductor Technologies at imec, oversees programs in logic, memory, photonics, and 3D integration. Previously, he was a senior director at GlobalFoundries, leading 14nm FinFET technology into production and developing 7nm CMOS. Starting his career at Motorola, he worked on strained silicon and other advanced materials. He holds a Ph.D. in materials science and engineering from MIT and a master's degree from Purdue University. Jo De Boeck, Executive Vice President and Chief Strategy Officer at imec, oversees the company’s strategic direction and serves on its executive board. He joined imec in 1991 after earning his Ph.D. from KU Leuven and has since held various leadership roles, including head of imec’s Smart Systems and Energy Technology business unit and CTO. De Boeck is also a part-time professor at KU Leuven. Maria Daniela Perez / Communications Manager, SEMI EuropePhone: +49 160 2562977Email: [email protected]

SEMI Europe's ongoing collaboration with key European industry players and governmental authorities on legislation such as the European Chips Act and critical topics including workforce diversity, sustainability, and supply chain resilience are crucial to the region’s future technological strength.

ISS Europe 2023 speakers focused on the influence of the EU Chips Act on the strategic direction of Europe’s semiconductor industry through 2030 and the legislation’s potential as a powerful instrument to strengthen Europe’s semiconductor industry.

ISS Europe 2023 speakers focused on the influence of the EU Chips Act on the strategic direction of Europe’s semiconductor industry through 2030 and the legislation’s potential as a powerful instrument to strengthen Europe’s semiconductor industry.

To support Europe’s industrial growth, SEMI Europe published a position paper with key recommendations on the proposed Kigali amendment to the Montreal Protocol to achieve the legally binding Greenhouse gas (GHG) reduction targets set by the 2021 European Climate Law [Regulation (EU) 2021/1119].