English

The refined EUV mask model

Applied Physics 2019-12-21 v1 Materials Science

Abstract

A refined model of an extreme ultraviolet (EUV) mask stack consisting of the Mo/Si multilayer coated by a Ru protective layer and a TaBN/TaBO absorber layer was developed to facilitate accurate simulations of EUV mask performance for high-NA EUV photo-lithography (EUVL) imaging. The model is derived by combined analysis of the measured EUV and X-ray reflectivity of a state-of-the-art mask blank. These two sets of measurements were analyzed using a combined free-form analysis procedure that delivers high-resolution X-ray and EUV optical constant depth profiles based on self-adapted sets of sublayers as thin as 0.25nm providing a more accurate description of the reflectivity than obtained from only EUV reflectivity. 'Free-form analysis' means that the shape of the layer-interfaces in the model is determined experimentally and is not given a priori by the structure model. To reduce the numerical effort for EUV imaging simulations a low-resolution model of the multilayer and absorber stack with sublayer thicknesses larger than 2nm, that fits to only the EUV reflectance, was derived from the high-resolution model. Rigorous high-NA EUVL simulations were done to compare the performance of the new model to our previous work.

Cite

@article{arxiv.1912.09075,
  title  = {The refined EUV mask model},
  author = {I. A. Makhotkin and M. Wu and V. Soltwisch and F. Scholze and V. Philipsen},
  journal= {arXiv preprint arXiv:1912.09075},
  year   = {2019}
}

Comments

This article has been submitted to the Journal of Applied Physics

R2 v1 2026-06-23T12:50:44.155Z