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Investigating extreme ultraviolet radiation chemistry with first-principles quantum chemistry calculations

H. Jonathan, Han Wang, David Prendergast, Andrew R. Neureuther, Patrick Naulleau

2020Journal of Micro/Nanolithography MEMS and MOEMS10 citationsDOIOpen Access PDF

Abstract

In extreme ultraviolet (EUV) lithography, chemistry is driven by secondary electrons. A deeper understanding of these processes is needed. However, electron-driven processes are inherently difficult to experimentally characterize for EUV materials, impeding targeted material engineering. A computational framework is needed to provide information for rational material engineering and identification at a molecular level. We demonstrate that density functional theory calculations can fulfill this purpose. We first demonstrate that primary electron energy spectrum can be predicted accurately. Second, the dynamics of a photoacid generator upon excitation or electron attachment are studied with ab-initio molecular dynamics calculations. Third, we demonstrate that electron attachment affinity is a good predictor of reduction potential and dose to clear. The correlation between such calculations and experiments suggests that these methods can be applied to computationally screen and design molecular components of EUV material and speed up the development process.

Topics & Concepts

Extreme ultraviolet lithographyExtreme ultravioletMolecular dynamicsChemistryElectronDensity functional theoryQuantum chemistryChemical physicsNanotechnologyComputational chemistryMaterials sciencePhysicsMoleculeSupramolecular chemistryOpticsQuantum mechanicsOrganic chemistryLaserAdvancements in Photolithography TechniquesElectron and X-Ray Spectroscopy TechniquesX-ray Spectroscopy and Fluorescence Analysis
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