Taiwan

The global semiconductor industry is entering a new phase of growth to keep pace with the increasing demand for artificial intelligence (AI), high-performance computing (HPC), and system-level integration. At the same time, rapid technological advancement is intensifying the need for highly skilled talent. Industry projections indicate that by 2030, the global semiconductor sector will face a shortage of more than one million professionals, making talent a critical variable shaping competitiveness and supply chain resilience.In this context, governments and industry organizations worldwide are accelerating efforts to develop talent pipelines and strengthen cross-border collaboration. For a highly globalized industry like semiconductors, the movement of talent and exchange of knowledge are no longer confined to individual markets, but are essential to the development of a resilient and interconnected global ecosystem. Increasingly, competition is extending beyond technological breakthroughs to the ability to build and sustain a global talent pipeline.Supported by a cross-border collaboration framework, SEMI and the UK Electronics Skills Foundation (UKESF) have jointly organized a program to cultivate the next generation of semiconductor talent. Through structured exchange mechanisms and close collaboration with industry, academia and public sector partners, the program connects global talent with real-world industry environments and contributes to building a more sustainable foundation for long-term workforce development.From Lab to Fab: Understanding the Path from Research to ManufacturingA core objective of the project is to bridge the gap between academic research and industrial application. Through a 14-day immersive experience combining industry engagement and hybrid learning formats, participants engage directly with experts and gain a system-level understanding of how the semiconductor industry operates—from research and development to high-volume manufacturing.The program covers key segments of the semiconductor value chain, including advanced research, wafer fabrication, IC design, packaging and testing, and system applications. This integrated learning experience enables participants to move beyond isolated technical knowledge and develop a broader understanding of how innovation is translated into scalable industrial capabilities.As one participant shared: “Experiencing the award-winning R D solutions at ITRI and the massive scale of wafer manufacturing at UMC firsthand was unforgettable. It was incredibly inspiring to see how advanced research is translated into global manufacturing capabilities—from lab to fab.”Participant feedback highlights a clear shift in understanding. Through hands-on learning and industry engagement, participants moved beyond isolated technical knowledge to develop a more comprehensive, system-level perspective of the semiconductor industry—supporting more effective collaboration across the global ecosystem.A Practice-Oriented Approach: Redefining Semiconductor Talent DevelopmentAs technology evolves and industry demands shift, traditional discipline-based education models are no longer sufficient to fully meet the needs of semiconductor manufacturing and R D environments. Increasingly, the industry is seeking talent with cross-disciplinary capabilities and hands-on experience.The project adopts a “learning by doing” approach, combining laboratory sessions, expert-led workshops, and company visits to provide participants with practical exposure to semiconductor devices, materials, process technologies, and system design. Participants also gain exposure to real-world applications such as chip security, design verification, and advanced process technologies.From an industry perspective, this approach aligns more closely with evolving workforce needs. Compared with conventional academic training, individuals with cross-disciplinary experience and international exposure are better equipped to understand the interplay between R D and manufacturing, and to integrate more effectively into real-world operational environments.UK participants, dressed in cleanroom suits, gained firsthand exposure to Taiwan’s semiconductor manufacturing environment—observing wafer fabrication equipment up close and engaging in hands-on learning to experience the journey from lab to fab.From Talent Development to Ecosystem ConnectivityAt a time when the semiconductor industry is entering its next phase of growth, talent plays a central role not only in driving innovation, but also in enabling global collaboration. As supply chains become increasingly interconnected, building mechanisms for cross-border talent mobility and cooperation is critical to strengthening both resilience and innovation capacity.At the program’s closing event, “UK–Taiwan Semiconductor Industry and Talent Exchange,” Terry Tsao, Global Chief Marketing Officer and President of Taiwan, SEMI, noted:“By 2030, the semiconductor industry is expected to require more than one million additional skilled professionals. Through international collaboration and industry–academia engagement, SEMI aims to enable more global talent to engage with Taiwan, gain a deeper understanding of its semiconductor ecosystem, and build long-term connections with the industry.”The project reflects a broader objective: not only to develop talent, but to build a sustainable, globally connected workforce network. By fostering a shared understanding and collaboration across borders, such initiatives help align capabilities and drive innovation across the global semiconductor ecosystem.Terry Tsao, Global Chief Marketing Officer and President of Taiwan, SEMI, emphasized the importance of nurturing globally connected semiconductor talent to help drive the industry’s future growth.Advancing Global Collaboration to Meet Long-Term Industry NeedsAs the industry continues to evolve, no single organization or region can address workforce challenges alone. Cross-border collaboration and structured talent development frameworks will be essential infrastructure for the future of the semiconductor industry.Looking ahead, SEMI will continue to expand international partnerships, connecting global industry, academia, and government stakeholders to deepen and scale talent development efforts—supporting the next generation of semiconductor professionals with both global perspective and practical expertise.For more information or partnership opportunities, please contact:Ily TsaiTel: +886-3-560-1777 [email protected] Ily Tsai is Project Manager, Workforce Development at SEMI Taiwan.

SEMI continues to establish new programs to address these four critical industry issues in Taiwan and support worldwide semiconductor industry growth and innovation.

With the emergence of consolidation as a potent engine of semiconductor industry growth, global mergers and acquisitions are sweeping the industry as companies look to accelerate advances across segments including data centers, AI, IoT and automotive chips.

Terry Tsao, Global Chief Marketing Officer at SEMI and President of SEMI Taiwan, recently discussed technology trends with Young Liu, Chairman of Hon Hai Technology Group (Foxconn), as a prelude to SEMICON Taiwan’s five online forums.

SEMI Taiwan and the Taiwan Semiconductor Manufacturing Co. (TSMC) Charity Foundation continue to work with the domestic chip industry to raise funds for donations of contactless rapid COVID-19 testing stations to hospitals.

Even though microchips continue to get smarter, vital security gaps continue to be exposed through such hack attacks as Meltdown, Spectre, and in recent weeks, Plundervolt. Researchers continue to discover open doors in chip architectures for malicious players to steal increasingly sensitive data, hide the identity of counterfeits, or tamper with electronics systems most anywhere along the global microelectronics supply chain. Today, it’s impossible to have full visibility of the distributed chip making process – from design and fabrication to packaging, testing and delivery. That’s why our industry’s future hinges to a large degree on establishing a hardware root of trust throughout the silicon’s operational lifecycle. Trust but verify! It’s easy to say, but how do we do it?To gain insights, SEMI interviewed Dr. Mark Tehranipoor, currently the Intel Charles E. Young Preeminence Endowed Chair Professor in Cybersecurity at the University of Florida’s Electrical and Computer Engineering Department. A foremost authority on microelectronics security and trust, counterfeit electronics detection, and supply chain risk management, Dr. Tehranipoor will be a keynote speaker at the SEMICON Taiwan Security on Chip Summit, Friday, September 25, where a full program of industry leaders will address key security challenges and solutions involving IoT, systems on a chip (SoCs), integrated circuits, physical unclonable function (PUF) technology, future design, certifications, managed services, and more.For additional insights and to hear Dr. Tehranipoor’s full presentation, register for SEMICON Taiwan 2020, which SEMI is holding as a hybrid event with both a virtual format and an in-show program September 23-25.SEMI: What are the major uncertainties in providing the hardware root of trust within the cyber domain?Tehranipoor: One of the most critical issues we’re dealing with now is loss of control over the process of designing and fabricating integrated circuits and systems. This has happened along with globalization and the movement of supply chain operations overseas to lower costs of nearly all goods, including electronics products and semiconductors. As skill sets, talent, design and fabrication have all shifted offshore, concerns have also risen about security controls across the many different segments of the microelectronics supply chain.For example, when you think about the security of military, space, transportation, power grids, financial or other networks, it becomes a major concern if you cannot trust the underlying electronics system that runs them. New SoCs are also holding more sensitive data around encryption keys, biometrics, personal information or banking data. And as reports escalate about cybersecurity gaps at the electronics part level, it’s increasingly important to establish a hardware root of trust. Today, it’s not enough for a buyer to just call up the design house and verify the electronic ID of an asset. The ID might match, but the device could have been tampered with or replaced with a counterfeit somewhere along its end-to-end journey. Unlike software or networks where problems can be automatically identified, upgraded and fixed, verifying electronic hardware is a costly and time-consuming process, especially when they’re as complex as microchips. It can take months to deconstruct, reverse engineer, inspect, and authenticate a chip. By then, discovery of any security breaches is too late.When addressing the security of electronics systems, there are three important features to keep in mind. First, there’s confidentiality. The device shouldn’t leak information to an unauthorized user. Second, there’s integrity. Unauthorized users should not be able to manipulate an SoC’s sensitive data. The third feature is availability, which can be a result of Denial of Service (DoS) attacks. If the device is under attack and can’t access your online service or network, you must still have security measures for your electronics system to be available in a safe mode while you simultaneously identify the problem, recover from it, and return to normal functions.SEMI: What framework should be followed to establish greater trust and confidence across the entire microelectronics supply chain?Tehranipoor: In the United States, we recognize it may not be possible to bring all manufacturing, design, and delivery teams back to this country and have them certified by the U.S. Department of Defense. You could do some of it, but it would be very costly and complex to bring back all the design, fab, testing, and packaging operations involved with electronics systems and still have complete control.The most practical approach is to make sure we design electronic systems with security and trust in mind from the start. We need to provide security features up front throughout the extended supply chain – into the design flow, fab flow, and out into the field to make it easier and faster for anyone at any point to verify the authenticity of an electronic system as well as identify and mitigate a problem. Finally, we have to remember that we are all in this together – designers, developers, packaging facilities and fabs. We can’t just blame semiconductor manufacturers or any other single entity. As a result, we must be cooperative and collaborative by focusing on this issue as a consortium. Everyone in this ecosystem must come to the table, share best practices, establish standards, and initiate best practices for device to system authentication.SEMI: How can SEMI and the SEMI Electronic System Design (ESD) Alliance help the industry meet these challenges?Tehranipoor: It’s certainly of utmost importance for members of organizations like SEMI and its ESD Alliance committees to jointly develop and adhere to standards or guidelines that establish hardware root of trust across all participants in the global supply chain. At the same time, such alliances should make it a high priority to protect each company’s intellectual property (IP). Collectively, we need resolutions that allow us to develop unique IPs and more easily trace, identify, and verify the authenticity of electronics systems as they flow throughout the end-to-end electronic supply chain. Great efforts are under way and progress is being made. But it’s not enough. Clearly, more needs to be done to establish root of trust standards at the chip level.I can’t emphasize enough the importance of consortia like the SEMI ESD Alliance to create an environment where industry, government, and academia can come together, share best practices and even case studies on how they handled security vulnerabilities and breaches. We understand that not everyone wants to share their security problems, vulnerabilities, or attack surfaces, but learning from each other’s experiences can have a tremendous impact on industrywide progress. If you don’t know what you need to address, you won’t be able to address it when it happens.I also encourage organizations like SEMI to create standards or guidelines that reduce the complexity of microchip designs for security purposes. Realtors often say there are three things to consider in finding a home that will appreciate in value: Location, location, location. To build more secure electronics systems, my mantra is: Automation, automation, automation. Complexity is the enemy of security. By using automation to simplify security mechanisms and detect inconsistencies, it will be easier to find and fix security problems, not to mention lower costs at the same time. SEMI: What will an attendee take away from your talk at SEMICON Taiwan?Tehranipoor: I have a large team of researchers who day and night spot vulnerabilities by attacking and assessing data from different electronic systems set up in our labs. Attendees will see real-world examples and lab animations that show how electronics systems can be hacked most anywhere across the supply chain. They will also learn about step-by-step security solutions we have developed at the microchip level. We need to do a better job of protecting the security of our semiconductor assets and the electronic solutions or services they power. My call to action will be that we need to invest more in research and foster an environment of more open trust and cooperation. We can do this by bringing together different countries, companies, and organizations in the microelectronics ecosystem to overcome this major challenge.Dr. Mark Tehranipoor is currently the Intel Charles E. Young Preeminence Endowed Chair Professor in Cybersecurity at the ECE Department, University of Florida. He is currently serving as Director for Florida Institute for Cybersecurity Research (FICS), National Microelectronics Security Training Center (MEST), CYAN Center of Excellence, and ECI Transition Center. He also serves as Program Director of Cybersecurity for UF Herbert Wertheim College of Engineering. His current research interests include IoT security, hardware security and trust, and reliable circuit design.Samer Bahou is senior manager of corporate communications at SEMI.

So far the semiconductor industry is outperforming most other manufacturing sectors. Semiconductor capital equipment shipments were up 23% globally in 2Q’20 vs. 2Q’19 and semiconductor chip 3/12 growth is still in positive territory. However there are signs of slowing.

2020 still looks to be a very difficult year. How we manage the pandemic, the global economy and international relations remain major challenges but there are glimmers of light near-term and a likely much brighter future in 2021 and 2022.

As the fight against COVID-19 presses ahead, many healthcare workers, especially those on the front lines, are being pushed to their limits and beyond to ensure our health and safety. To help doctors and nurses combat the virus, SEMI Taiwan mobilized six leading Taiwan semiconductor companies last month to donate personal protective equipment (PPE) designed for industrial operation to medical staff. The gear included powered air purifying respirators (PAPR), half facepiece respirators, head tops, protective coveralls, and air filter canisters.On behalf of the semiconductor industry, SEMI Taiwan worked closely with industry leaders and the government to deploy the direly needed resources to support the domestic medical community. The Taiwan Association of Medical Technologists accepted the donations in the ceremony attended by Taiwan CDC Deputy Director-General Chuang Jen-hsiang. The largesse is the result of public-private partnership to provide medical supplies to 35 hospitals and medical laboratories across Taiwan. Terry Tsao, Global Chief Marketing Officer and President of SEMI Taiwan, and six Taiwan semiconductor companies stepped up to help combat the coronavirus pandemic. TSMC Charity Foundation responded with PPE giveaways in March in a first wave of protective equipment donations to medical personnel. Before long, Vanguard International Semiconductor Corporation (VIS), ​​​​​​​​​​​Macronix, Micron, United Microelectronics Corporation (UMC), and 3M Taiwan also answered the call for more medical equipment for COVID-19 frontliners. Extending the Taiwan semiconductor industry’s rich tradition of making charitable contributions in the region, including financial assistance for emergency relief efforts, the companies donated more than 1,000 pieces of PPE after balancing the giveaway with inventory needs in their fabs. Fab workers responsible for machinery, raw materials, and other goods and gear used in semiconductor manufacturing wear the protective devices. One piece of equipment, powered air purifying respirators (PAPR), features a battery-powered that sends filtered air flowing into a hood or head top covering the wearer’s head or face to protect against respiratory hazards. In healthcare, PAPRs protect medical staff as they test blood and tissue samples for traces of COVID-19. Dr. N.S. Tsai, CEO of TSMC Charity Foundation, notes that respiratory protection equipment can offer integrated protection against multiple hazards and is comfortable for medical technologists working long shifts to wear. Medical facilities across Taiwan quickly depleted PPE supplies after the rapid response to the January outbreak by healthcare providers across the region led to quick containment. The PPE donations were critical in minimizing exposure risks to medical staff. The chip industry’s protective clothing and equipment offered another benefit: Medical technologists found the gear – designed to be worn over long periods in semiconductor manufacturing facilities – comfortable as they worked marathon shifts early in the COVID-19 outbreak. “Coronavirus testing requires a much higher level of protection than is needed in many healthcare settings,” said Chuang Jen-hsiang, the Deputy Director for the Taiwanese Centre for Disease Control (CDC) and the spokesperson of Taiwan Central Epidemic Command Center. “Medical technologists must work in a poorly ventilated labs for more than eight hours a day, causing sweating and damp heat. The high-performance PPEs provided by the industry help healthcare workers breathe more naturally without wearing a mask while greatly reducing infection risk in hot, humid environments.”For their COVID-19 response, Taiwan’s government and well-trained medical workers drew lessons from the SARS outbreak in 2003 to quickly activate emergency management structures to fend off the emerging threat – one that put the Taiwan semiconductor industry and its round-the-clock operations at risk.“Taiwan’s swift response to the COVID-19 was vital in preserving the business continuity that is the lifeblood of the semiconductor manufacturing,” said Terry Tsao, Global Chief Marketing Officer and President of SEMI Taiwan. “We are honored to do our part to support the heroes of this fight – the medical technologists on the front lines – as an expression of our great respect and gratitude for their extraordinary work.”SEMI Taiwan has long partnered with TSMC Charity Foundation to care for people in need, drive positive environmental and social changes, and support emergency aid in Taiwan. The goal our joint corporate social responsibility efforts is to warm the hearts of our people and build a better society.Irene Huang is a public relations and marketing specialist at SEMI Taiwan.

Companies around the world are increasingly turning to mergers and acquisitions, research and development, and corporate venture capital (CVC) investment to sustain growth. For many years, global semiconductor companies including Intel, Qualcomm and Samsung have been active CVC investors. However, the economic fallout from the COVID-19 pandemic has forced many venture capital (VC) and CVC investors to rethink their investment strategies as they look to an uncertain future. To help provide SEMI members with the latest market trend information, SEMI Taiwan held the webinar Challenges and Opportunities in Corporate Venturing during the Global Pandemic Crisis on April 28th. Featured speaker James Mawson, founder and editor in chief of Global Corporate Venturing, provided an analysis of the pandemic’s impact on deal flow, capital movement, sentiment and strategies among CVCs. CVC takes larger role in past decadeCorporations have been increasingly active direct and indirect venture investors over the past decade. From 2011-2019, more than US$1.3 trillion of venture capital was invested globally, with corporations accounting for more than half that total, according to data from Pitchbook/GCV Analytics.Semiconductor companies that have been active in corporate venturing include Intel, Samsung, Nvidia, ARM, AMD, SK Hynix, Broadcom and Qualcomm. Pure-play semiconductor and chip companies tend to make few investments in their start-up counterparts because sector saturation of powerful incumbents leaves little opportunity for growth, James said. “While it is hard to find entrepreneurs wanting to be engaged in pure play S C, once they do, they can be very valuable and often be able to bring disruptive forces to the whole ecosystem,” James said.S C corporate investors focus on chip applicationsSemiconductor companies looking beyond pure-play S C start-ups for investment opportunities often target applications or developers that require the additional data, processing power, and memory their chips provide. “There is lots of interest by the big chip companies such as Intel, Qualcomm, and Samsung in developing some of those chip applications, getting them used more and creating a whole ecosystem,” James said.For example, Intel Capital, based on its data-centric theme, has focused on areas like autonomous vehicles, data centers and artificial intelligence (AI) because of the sheer amount of data and processing power they require. In another notable trend, non-traditional S C players such as Apple and Alibaba are leveraging investments in start-ups to develop their own chips for competitive advantage, James said.March deal flow down 20% With COVID-19 slowing the global economy, James expects semiconductor and chip companies to scale back direct investments this year due to rising pressure on their balance sheets. Deal flow in March was down roughly 20% from February.James is hopeful corporates will focus on investing in innovation over the long term rather than target share buybacks to boost near-term earnings. James pointed out that investors can uncover opportunities by identifying future problems to be solved in areas such as quantum computing, biotech, energy, healthcare, communications and ICT. Still, in the near term, where there is a crisis, there is opportunity. While the pandemic hit some sectors hard, it benefits start-ups in industries including gaming, education and telemedicine. This time is different?James said corporates need to rethink the investment model they want to follow. One option is the approach taken by General Electric, which divested its investment team and sold all its portfolio companies last year. Another is to focus on the long term. For example, Intel Capital has been dedicated to investments in innovation for nearly 30 years and continues to invest during downturns.Compared with the internet bubble and global financial crisis, today there are more experienced and mature CVCs that better know how to negotiate a crisis. James also pointed out investors are interested in backing CVCs with sector investing experience. There are now more than 600 CVCs with a 10-year-plus track record.James expects a variety of funding models to emerge over the next decade as pressure on corporate balance sheets encourages corporate investors to consider models that allow third-party capital to effectively leverage their CVC units. Corporate investors are also open to other ways to efficiently deliver financial returns.For more information about the SEMI Taiwan Corporate Growth and Innovation Community, please contact Irene Lin at [email protected]. For GCV’s latest news and event, visit its website.Jo-Ann Su is senior director of the Corporate Growth and Innovation Community at SEMI Taiwan.