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IJAT Vol.19 No.5 pp. 879-889
doi: 10.20965/ijat.2025.p0879
(2025)

Research Paper:

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Real-Time Interfacial Pressure Prediction in CMP Using Machine Learning Surrogates of Finite Element Simulations

Tom Rothe*,***,†, Andre Lauff**, Alexey Shaporin*,*** ORCID Icon, Peter Thieme**, Mudassir Ali Sayyed*,*** ORCID Icon, Knut Gottfried***, Jörg Schuster*,*** ORCID Icon, Jan Langer*** ORCID Icon, Linda Jäckel*,*** ORCID Icon, Martin Stoll* ORCID Icon, and Harald Kuhn*,*** ORCID Icon

*Chemnitz University of Technology
Straße der Nationen 62, Chemnitz 09111, Germany

**Infineon Technologies Dresden GmbH & Co. KG
Dresden, Germany

***Fraunhofer Institute for Electronic Nano Systems ENAS
Chemnitz, Germany

Corresponding author

Received:
February 5, 2025
Accepted:
June 28, 2025
Published:
September 5, 2025
Creative Commons License
Keywords:
chemical-mechanical polishing, machine learning, semiconductor process modelling, surrogate modelling, finite-element simulation
Abstract

Achieving uniform material removal in chemical-mechanical polishing requires precise tuning of interfacial pressure. High-fidelity finite-element simulations can accurately model pressure profiles essential for this tuning process. However, these simulations are too computationally intensive for extensive parameter studies. This work introduces a surrogate modelling approach for two-dimensional radial pressure profiles in five-zone polishing heads. Functional principal component analysis identifies a compact, data-driven basis from a dataset of finite-element-generated pressure profiles. Kernel ridge regression then maps applied zone loadings to the extracted coefficients. Validation across diverse loading scenarios shows that the proposed surrogate matches the accuracy of detailed finite-element simulations while delivering millisecond-level predictions and clear interpretability which inputs drive specific pressure‐profile changes. Researchers with existing high-fidelity models can adopt this framework to develop fast, interpretable surrogates for real-time process optimization.

Cite this article as:
T. Rothe, A. Lauff, A. Shaporin, P. Thieme, M. Sayyed, K. Gottfried, J. Schuster, J. Langer, L. Jäckel, M. Stoll, and H. Kuhn, “Real-Time Interfacial Pressure Prediction in CMP Using Machine Learning Surrogates of Finite Element Simulations,” Int. J. Automation Technol., Vol.19 No.5, pp. 879-889, 2025.
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Last updated on Sep. 05, 2025