European Union

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]

At SEMICON West 2023, experts discussed the growing legal and regulatory risks facing the semiconductor industry and how to navigate those risks through the pursuit of sustainability strategies and broader industry collaboration on policy development.

The United States leads the world in COVID-19 vaccine availability and is on pace to amass the supply necessary to inoculate its full population by July, a leading business consulting firm said at a recent SEMI webinar.

On April 21, 2021, the European Commission put forward the long-awaited Proposal for a Regulation on a European approach for Artificial Intelligence, introducing for the first time harmonized rules for the development, placement and use of secure and ethical artificial intelligence (AI) in Europe. The proposed regulation’s wide scope subjects providers, importers, distributors, and users of AI systems to regulatory scrutiny. It also includes providers and users outside of the European Union (EU) that deploy AI systems or use AI system outputs in the EU. With extraterritorial scope, the proposed regulation aims to further strengthen the EU’s leadership in shaping global standards and norms for new technologies. A European Path to Safe AI Following a risk-based approach, the proposed regulation classifies AI systems according to the level of danger they pose in the following categories: Unacceptable risk: AI poses unacceptable risk to systems or applications with the potential to manipulate human behavior and exploit vulnerabilities of groups of people to cause psychological or physical harm. Examples of prohibited AI systems include social-scoring systems and biometric identification that can be used by public authorities. High risk: The proposal identifies two main categories: AI systems used as safety components of products (or are a product themselves), and other stand-alone AI systems that have fundamental rights implications. Considering their intended purpose, the proposal identifies specific conformity assessment measures for both groups. AI systems intended to be used as security components will require a conformity assessment by an independent third party. Such systems will also be subject to the same ex-ante and ex-post compliance and enforcement mechanisms as products of which they are part. In contrast, stand-alone AI systems assessed through internal checks would require ex-ante compliance with all requirements of the regulation as well as with robust standards for quality and risk management and post-market monitoring. The proposed regulation identifies eight areas of high risk including AI systems in safety components of products (e.g., machinery, radio equipment, AI applications in robot-assisted surgery), critical infrastructures (e.g., transport), educational and vocational training (e.g., exam scoring) and employment (e.g., monitoring or evaluation of persons in work-related contractual relationships). Prior to their introduction to market, high-risk AI systems will be a subject to strict requirements including the use of high-quality datasets; adequate risk assessment and mitigation systems; high levels of robustness, accuracy, and security; clear and adequate user information; detailed system documentation and logging of activities to ensure traceability of results. Human oversight and control must be ensured. Low and Minimal risk: For limited-risk AI systems (e.g., chatbots), the regulation proposes only minimum transparency obligations, while minimal risk AI systems posing little to no risk (e.g., AI in spam filters) will not be regulated. Boosting AI Excellence from Lab to Market Continuous innovation of AI requires a secure environment that can support responsible validation of AI technologies. To that end, the proposal encourages the set-up of testing and experimentation facilities or so called AI regulatory sandboxes. Established by one or more Member States, the sandboxes will provide a controlled environment to test innovative technologies under strict oversight before their market introduction. These facilities could play an instrumental role in connecting the Europe’s R D ecosystem, creating new partnerships among numerous stakeholders. In addition to regulatory sandboxes, the European Commission intents to set up: A Public-Private Partnership (PPP) on AI, data and robotics designed to implement and invest in strategic research innovation and a deployment agenda for Europe Additional Networks of AI Excellence Centers to foster exchange of knowledge and advance collaboration with the industry Testing and experimentation facilities to test state-of-the-art technology Digital Innovation Hubs, one-stop shops to provide access to technical expertise and experimentation An AI-on-demand platform as a central European toolbox of AI resources (e.g., expertise, algorithms, software frameworks and development tools). Next Steps The proposed regulation is the at the start of a lengthy legislative process and will be debated by the European Parliament and European Council in the coming months. Given the importance of AI, and number of stakeholders involved, it is likely the proposed regulation will face various changes before being applied across the EU. For its part, SEMI Europe will maintain discourse with key public and private stakeholders on the proposed regulation, closely monitoring related policy developments as they unfold. Marek Kysela is senior coordinator of Advocacy at SEMI Europe.