Modeling photon, electron, and chemical interactions in a model hafnium oxide nanocluster EUV photoresist

Despite years of research and development, the fundamental processes of photoionization, secondary electron generation, recombination, diffusion, and resist switching are poorly understood at the atomic level for EUVL. Multiscale modeling of these physical and chemical processes can provide answers to questions that are difficult or impossible to answer with experiment alone. A modeling pipeline that includes Monte Carlo modeling of photon- and electron-matter interactions, along with density functional theory calculations of chemical switching will be introduced in this proceeding. The Hf₄O₂(OMc)₁₂ nanocluster resist will be presented as a case study. Photon and secondary electron yields, electron energy and spatial distributions, and a quantum chemical pathway for negative tone switching will be presented. Fundamental learning from studies like this can be used to improve resist design including improving contrast of these materials.