Silicon-Rich Materials for Advanced Semiconductor Fabrication

Semiconductor chips empower all modern digital technology and are an integral part of our lives. Only a handful of companies can produce them in their advanced forms or equipment and materials for the nanometre-scale precision required for their manufacture.

Extreme ultraviolet (EUV) lithography is the key process to achieve 3 nm node in semiconductor manufacturing. Development of the EUV materials to meet the process requirements has been crucial and challenging. Chemically amplified photoresists (CARs) have been widely used in EUV lithography due to its high sensitivity. However, as the feature size reduces further, it has reached the limit of pattern resolution and etch resistance of CARs. PiBond is one of two companies globally who have innovated inorganic EUV materials meeting future needs. The inorganic EUV materials have the potential to achieve better lithographic performance, in terms of resolution and etch resistance, than CARs. Yet the development of underlayers that can assist the performance of photoresists is also crucial.

This high-risk project enables us to unlock a significant portion of advanced chips market of >500Bn€ and SAM of >3Bn€ in photoresist materials. Our project is critical for the EU goals in semiconductor manufacturing (Chips Act).

The project advanced both Si-based and metal containing EUV photoresist technologies through extensive material development, process optimization and industrial collaboration. The Si photoresist formulation was finalized with repeatable synthesis, compliant trace-metal levels, solvent compatibility and demonstrated stability of at least three months. Quality assurance aspects and material application guidelines of Si photoresist were also completed. In parallel, the development of new metal-containing resist platform was initiated, with synthesis methods refined to meeting industrial trace-metal level requirements and high resolution EUV patterning achieved down to P24 nm.

• The synthesis and formulation of the Si photoresist have been finalized. The material meets industrial requirements in terms of impurity levels and solvent compatibility. EUV patterning performed on industrial equipment demonstrates strong potential for use as a silicon-based patternable hardmask. A scaled up product batch has been produced and shows performance comparable to the lab scale samples, with formulation stability demonstrated for up to three months. Future work will focus on exploring potential markets using a bi-layer integration concept and improving shelf life stability for production-scale formulations.
• The development of metal-containing EUV materials—applicable both as underlayers and as photoresists—has progressed substantially during the project. Five patents on the new concept have been filed. The underlayer materials demonstrated excellent etch selectivity and were requested by customers for demonstration. The metal-containing photoresist achieved high-resolution EUV patterning down to P24 nm. Synthesis and formulation procedures have been optimized to meet industrial requirements, demonstrating good reproducibility. Further work will focus on improving sensitivity and advancing the material for next generation nodes.
• The project did not participate directly in standardization or regulatory efforts. However, we monitored relevant developments and ensured that the technologies and materials developed remain compliant with ECHA and other applicable regulatory frameworks, including anticipated EU-wide legislative requirements.
Overall, the project delivered substantial progress and delivering key performance milestones, demonstrating industrial compatibility, and obtaining early external validation for both Si-based and metal-containing EUV photoresists. These outcomes provide a strong foundation for continued development and potential commercialization.