microelectronics

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

Despite the pandemic lock-down, demand for electronic products and services remains strong. Work-from-home, video conferencing, and remote learning are driving data center growth and laptop and tablet demand. 5G infrastructure rollout is underway and smartphone sales are returning to normal levels. Automotive sales are increasing. At the same time, the industry is experiencing acute shortages of substrates. The October 2020 fire at Unimicron’s IC package substrate plant in Taiwan exposed the serious nature of the capacity shortage for IC package substrates. Substrate makers have been reluctant to make large investments in capacity over the last few years due to the fear that demand could decline and they would have excess capacity. Relentless price pressures by customers and the resulting low margins have weakened the finances of substrate suppliers. With tight capacity, substrate prices have increased and lead times are 14 weeks or more. The most critical shortage is for flip chip ball grid array (FC-BGA) substrates. In addition to increased demand in units, applications such as servers and networking products are seeing requirements for larger body sizes and increased layer counts. Shortages will not improve very soon because it takes time to build a new plant. And equip it. Key equipment for substrate production has lead times of up to a year. SEMI and TechSearch International detailed the substrate makers and provide projections for the substrate market, trends, and a list of suppliers and their plant locations in the Global Semiconductor Packaging Materials Outlook report. The report also highlights the market and suppliers for leadframes, bonding wire, encapsulation materials, underfill, die attach, solder balls, wafer level package dielectrics, and wafer-level plating chemicals. In times of shortages the report is an important indicator of suppliers in the industry and trends. Jan Vardaman is President at TechSearch International Inc.

SEMI spoke with Dr. Franz Laermer, Research Fellow (Senior Chief Expert) at Robert Bosch GmbH Stuttgart, Corporate Sector Research and Advance Engineering, about the latest trends in medical diagnostics and personalized treatments. An open platform for the automation of complex molecular diagnostics workflows recently developed by Robert Bosch has proven its ability to take molecular diagnostics to the point of need.To make this happen, miniaturization, microsystems and microfluidics technologies, as well as microelectronics, are crucial. This is critical for the detection of SARS-CoV-2 infections within a rather short development time.Laermer shared his views ahead of his presentation at the SEMI MedTech Forum, 19 February, as part of the SEMI Technology Unites Global Summit, 15-19 February 2021, online event. Join us to meet experts from Robert Bosch and other key industry influencers. Registration is open. SEMI: What is driving innovation in diagnostics and what role does the semiconductor industry play?Laermer: One of the major drivers in diagnostics is the molecular breakdown and detailed analysis of nucleic acids on the level of the individual nucleotide. This reveals the root causes of diseases like cancer, genetic aberrations, infections and therapy resistances. Today’s solutions are mostly PCR-based (that rely on the polymerase chain reaction) or depend on sequencing. The keys to bring these technologies closer to the point of need are automation, miniaturization, low-cost, ease of use, flexibility, reliability, and fast time from sample-to-result. Semiconductor and microsystems technologies are enablers to meet these requirements, thanks to their ever-increasing performance, with Moore’s law pushing the semiconductor side of the story.SEMI: Can you tell us more about the the Bosch VIVALYTIC system? Laermer: VIVALYTIC is a universal and highly flexible diagnostic platform for the integration and automation of a wide variety of molecular diagnostics assays. It consists of the universal laboratory analyzer tool, which operates the application-specific cartridges. All reagents and specific bio contents are contained in the application-specific cartridges in a long-term stable manner at room temperature. The user only has to introduce the patient sample into the cartridge, push the cartridge into the analyzer and start the automatic workflow, which yields a diagnostic result within typically less than one hour. The VIVALYTIC products are manufactured by Bosch Healthcare Solutions GmbH (BHCS) in cooperation with strategic diagnostic partners and bio content owners.SEMI: How is the pandemic impacting automated diagnostics in the medical industry? What is new now?Laermer: The pandemic has clearly shown the importance of fast automated diagnostics at the point of need. Breaking infection chains as early as possible requires fast reliable PCR testing anywhere and anytime. We managed to reduce the time needed for SARS-CoV-2 rapid testing to less than 30 minutes for positive probes, an achievement that is embraced by our customers. Until a sufficiently high level of immunization is reached by vaccination, rapid testing is the only way to limit the number of infections, hospitalizations, and lethal outcomes of the COVID-19 pandemic.SEMI: Besides infectious disease diagnostics, what solutions will enable a paradigm shift in medical treatments?Laermer: Today more and more targeted drugs and therapies are developed in oncology to address certain mutations that are considered drivers of the cancer. This moves away from the one drug fits all approach to precision oncology. As a prerequisite of this personalized therapy, the mutation status of a tumor must be clarified – and monitored precisely and repetitively during therapy. The latter requires molecular diagnostics at the point of need, i.e. at the onco-ambulance. One keyword in this context is liquid biopsy. Another example of personalized therapy is the detection of bacteria type and antibiotics resistances in bacterial infections, and the selection of optimized antibiotics therapy.SEMI: What solutions can Robert Bosch bring to address the needs just mentioned? Laermer: Robert Bosch GmbH is a leader in microsystems, microsensors and semiconductor technologies. Our new 12-inch semiconductor plant in Dresden will strengthen our position in these fields. This encompasses artificial intelligence and the Internet of Things as well. As a technology provider, we generate superior solutions for automation and management of complex workflows, and thus deliver win-win-solutions together with our diagnostic partners.SEMI: How can technology unite us? Laermer: Technology, especially semiconductor and microsystems technology, is a game changer in the medical area. Whenever different disciplines meet each other and cooperate, as are the medical, diagnostics and semiconductor areas, innovation is accelerated strongly. New things happen at the interfaces between different areas of competencies.Franz Laermer, Research Fellow (Senior Chief Expert), Robert Bosch GmbH Stuttgart, Corporate Sector Research Advance Engineering. Dr. Franz Laermer joined the Corporate Research and Technology Center of Robert Bosch GmbH, Stuttgart, Germany, in 1990, where he started the development of new key technologies and sensor functions for the upcoming field of MEMS at Bosch. Today he is a Bosch Research Fellow/Senior Chief Expert for Microsystems, Microfluidics and Molecular Diagnostics. Laermer's work laid the foundation for the VIVALYTIC Diagnostics Platform of the newly founded Bosch Healthcare Solutions (BHCS) Business Division and the SARS-CoV-2 rapid tests from Bosch. Dr. Franz Laermer is the co-inventor of the Bosch Deep Reactive Ion Etching Process (BOSCH-DRIE) for microstructuring silicon. He holds more than 200 patents and was awarded with European Inventor of the Year 2007 – Category Industry prize by the European Commission and the European Patent Office (together with co-inventor Andrea Urban) for the invention, development and sustainable success of the BOSCH-DRIE process. He received the 2014 IEEE Jun-ichi Nishizawa Medal Award from the Institute of Electrical and Electronics Engineers (IEEE), USA. In 2019 he was awarded with the 2019 Technology Prize from the Eduard-Rhein-Foundation in Germany.Serena Brischetto is senior manager of Marketing and Communications at SEMI Europe.

A lot has happened in fifty years, particularly when it comes to the microelectronics industry. Founded in 1970 by a group of semiconductor industry pioneers who believed that co-opetition — instead of traditional competition—would produce a more vibrant emerging industry, SEMI was born as an industry association.It's fitting during this week’s 50th annual SEMICON West (July 20-23, 2020) — a virtual event for the first time — that SEMI Chief of Staff Bettina Weiss offers her perspectives on the evolution of SEMI from one of the best seats in the house: the 24 years that she has spent helping the association change and grow.Vetrano: You’ve enjoyed a long rich history with SEMI, and now serve as the association’s first chief of staff. What roles have you played at SEMI up to this point?Weiss: I cut my teeth at SEMI by joining SEMI Standards, first serving as standards coordinator at SEMI Europe from ’96-’97. Over the next 11 years, I held a variety of positions at SEMI Standards, culminating with director of international standards from 2003-2008. Given that experience, I have to admit that SEMI Standards are still near and dear to my heart.I moved on to several leadership positions in our former global photovoltaics/solar business through 2014, and toward the end of that stint, I assumed additional responsibilities, becoming vice president of business development. That’s where I dove headfirst into expanding SEMI into emerging regions, including Vietnam, India and Latin America. SEMI goes where members see (or want to better understand) new opportunities, especially in places that had ambitious plans for fabs for microelectronics, including semiconductors and MEMS.In 2018, I became SEMI chief of staff, reporting directly to our president and CEO Ajit Manocha.Vetrano: Now I hardly know where to start! Since I have to decide, what does it mean to be SEMI chief of staff?Weiss: As the first chief of staff, I’ve been able to shape the position, combining the support of critical efforts driven by Ajit with additional project management responsibilities like our Smart Mobility initiative.Working with experienced leaders in our industry, such as the Board of Industry Leaders (BIL), is one of the more rewarding parts of my role at SEMI. The BIL is a group of global executives tasked with advising SEMI on strategic planning, especially when it comes to future-looking initiatives like Smart Mobility, Smart MedTech, Smart Manufacturing, and Smart Data/AI.A lot of the other things I do are meant to support the whole SEMI organization, in partnership with other senior leaders such as Michael Ciesinski, vice president of technology communities, as we create business plans and examine new revenue models that will keep SEMI sustainable and viable for the future. This includes issues as varied as workforce development and diversity and inclusion, and the new digital platforms we use to engage with our members.Vetrano: How does SEMI Smart Mobility initiative exemplify the model of engaging end customers in vertical markets that are important to members?Weiss: When you look at the rapidly increasing number of chips and sensors in and around vehicles, Smart Mobility at its core brings together both the semiconductor/sensor and automotive/mobility supply chains for a more transparent dialogue about needs and wants along the entire supply chain. We are thrilled to count automotive OEMs Volkswagen and Audi as SEMI members. We also work with Tier 1 suppliers such as Continental and many others to promote the open exchange of ideas and foster collaboration among all stakeholders.Smart Mobility is a good example of how SEMI connects two worlds that are now interdependent for the mutual benefit of all players. Automotive companies and component suppliers want to better understand new technology capabilities that enable tomorrow’s infotainment, safety, security and communication protocols. And semiconductor, sensor and component companies see huge upside in supplying the equipment, materials, devices and subsystems that enable the future of mobility. Smart Mobility is a win-win, and the founding concept of our Global Automotive Advisory Council (GAAC).Vetrano: As we look to COVID-19, the single most important event to influence the microelectronics industry — and every other industry — why is SEMI membership more important now than ever?Weiss: Our industry is facing a triple whammy of challenges: a global pandemic, ongoing global trade tensions that impact interdependent supply chains, and a global economic crisis. All these challenges will require our members’ ingenuity, innovation and collective action to overcome them. But inherent in those challenges are tremendous opportunities, and I have no doubt that our members and the entire global electronics ecosystems will find ways to help everyone prosper and advance.COVID-19 has had a huge impact on our members. From the onset of the pandemic, we’ve provided our members with resources including best business practices, insights and data from industry experts to help them respond to a virus that has already changed so many things we took for granted before March. Additionally, SEMI has also advocated with governments around the world on behalf of the industry for essential business status and essential travel to sustain operations. Visit SEMI COVID-19 Resource page for information on industry best practices and much more.Vetrano: Before we look forward, what has changed dramatically in microelectronics since you started at SEMI?Weiss: Through my work with SEMI, I’ve witnessed dynamic, dramatic and sustained change in the microelectronics supply chain. Into the late 1990s, SEMI represented primarily semiconductor equipment and materials suppliers, and we worked with chipmakers – our members’ customers. That’s where a lot of important Standards work happened, for example, and the supplier-device maker relationship was pretty much our world. Over the years, we saw significant change in how companies partner and do business with one another. The digital transformation we’ve been witnessing for the past few years was the impetus for expanding our reach to bring companies in the extended electronics manufacturing and design supply chain together, from sand to system, so to speak. That was also when we invited associations representing flexible hybrid and printed electronics (FlexTech), MEMS and sensors (MSIG), and electronic system design (ESD Alliance) companies to join SEMI and our other technology communities for maximum cross-pollination. That’s because everything needs microelectronic devices and systems. Vetrano: Looking ahead now, what is can the microelectronics industry do to benefit humanity?Weiss: Semiconductors and sensors are often the unsung heroes of progress. Microelectronics can help bring prosperity to the billions of people now struggling on our planet. It can improve access to education for people through e-learning, it can advance agricultural production and streamline the food supply chain to help feed the world’s hungry, it can monitor the quality of the water we drink and the air we breathe, and it can get you in front of a doctor even in the most remote village in India.The beauty of microelectronics is that we are not gated by innovation. As the brilliant visionary Arthur C. Clarke once said, “The only way of discovering the limits of the possible is to venture a little way past them into the impossible.”As an industry association that helps technologists to venture beyond “the limits of the possible,” I invite like-minded technology adventurers to engage with SEMI, starting with registration to this week’s SEMICON West – our first virtual show.As chief of staff, Bettina Weiss reports to SEMI President and CEO Ajit Manocha and manages a broad portfolio of responsibilities. Major focus areas include advancing specific global strategic initiatives such as thought leadership (Think Tanks) and SEMI Smart Transportation vertical application platform, improving organizational efficiency, alignment and financial sustainability, acting as senior liaison to SEMI Board of Industry Leaders, leading strategic partnerships and M A activity, and supporting Manocha in creating a highly effective, agile global association.Maria Vetrano is a PR consultant at SEMI.

The White House and House Speaker Nancy Pelosi announced that the United States has reached final terms on the U.S.-Mexico-Canada free trade agreement (USMCA). The USMCA provides important modifications and updates to the 25-year old North American Free Trade Agreement (NAFTA), and SEMI supports its timely ratification in the U.S. Congress. The USMCA includes significant provisions to protect continued innovation and North American market access across product design and manufacturing supply chains for the electronics industry. The agreement strengthens requirements for the protection and enforcement of intellectual property rights, including trade secrets. The U.S. microelectronics industry will benefit greatly from USMCA’s strong enforcement mechanism for the misappropriation of trade secrets including civil procedures and remedies, criminal penalties, and judicial procedures to prevent disclosure of trade secrets in litigation.The agreement also establishes new rules to enhance and protect digital trade to benefit companies of all sizes and consumers. The USMCA prohibits tariffs, taxes and other barriers to cross-border data flows and minimizes restrictions on where data can be stored and processed. These provisions establish important precedents for data and digital technology in future trade agreements. The USMCA aligns with SEMI’s core principles including open global markets, fair competition and the protection of intellectual property rights. Mexico and Canada are two of the United States’ most important trading partners, and strengthening the three countries’ mutual obligations under USMCA will greatly benefit SEMI members. SEMI welcomes final passage of the USMCA and the critical certainty it will bring to trade rules within North America going forward.Joe Pasetti is Vice President, Global Public Policy Advocacy, at SEMI.