Towards molecular-scale kinetic Monte Carlo simulation of pattern formation in photoresist materials for EUV nanolithography

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Samenvatting

Modelling the pattern formation process in photoresist materials for extreme ultraviolet (EUV) lithography in a stochastic and mechanistic manner, with molecular-scale resolution, should enable predicting the effect of variations of material parameters and process conditions, leading to insights into the ultimate resolution limits. In this work, we present the results of the first steps toward that goal. We describe the physics of the development with time of cascades of electrons and holes, created by the stochastic absorption of 92 eV photons, using a kinetic Monte Carlo model with molecular resolution. The thin film material is modelled assuming a cubic array of lattice sites, at a distance that is consistent with the molecular density of the photoresist material that is considered. The simulation of the cascading process is based on the experimental optical energy loss function, extended to include also excitations with momentum transfer. The method allows for including the Coulomb interactions between charges. In contrast to earlier work, within which the high-energy electrons move ballistically until scattering takes place, the trajectories are in our model formed by stochastically determined interconnected molecular sites. In future extensions of the model, this approach will facilitate including in a natural way a transition from delocalized electron transport at high energies to hopping transport of localized electrons at low energies. The simulations are used to study the sensitivity of the average number of degradations per absorbed photon and the average electron blur length on the rates of elastic scattering and of molecular degradation, and on the energy that is lost upon a molecular degradation process.

Originele taal-2Engels
TitelAdvances in Patterning Materials and Processes XL
RedacteurenDouglas Guerrero, Gilles R. Amblard
UitgeverijSPIE
Pagina's1-9
Aantal pagina's9
ISBN van elektronische versie9781510661042
ISBN van geprinte versie9781510661035
DOI's
StatusGepubliceerd - 2023
EvenementAdvances in Patterning Materials and Processes XL 2023 - San Jose, Verenigde Staten van Amerika
Duur: 27 feb. 20231 mrt. 2023

Publicatie series

NaamProceedings of SPIE - The International Society for Optical Engineering
Volume12498
ISSN van geprinte versie0277-786X
ISSN van elektronische versie1996-756X

Congres

CongresAdvances in Patterning Materials and Processes XL 2023
Land/RegioVerenigde Staten van Amerika
StadSan Jose
Periode27/02/231/03/23

Bibliografische nota

Publisher Copyright:
© COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.

Financiering

This publication is part of the project “Molecular-scale model of pattern formation in EUV-lithography photoresists: towards ultimate resolution limits” (MM2ULTIM), with Project No. 17966, of the research programme “High Tech Systems and Materials” of the Netherlands Organization for Scientific Research (NWO). The project is jointly financed by NWO and Simbeyond B.V. The authors thank prof. Fred Brouwer (University of Amsterdam and ARCNL), dr. Sonia Castellanos-Ortega (Inpria), dr. Harm van Eersel (Simbeyond), dr. Stefano Gottardi (Simbeyond), dr. Kees Hagen (TU-Delft) dr. Frank de Jong (Thermofisher Scientific), dr. Peter Kraus (ARCNL), prof. Sense Jan van der Molen (Leiden University), dr. Danilo De Simone (IMEC) and dr. Engin Torun (Simbeyond) and for useful discussions. This publication is part of the project "Molecular-scale model of pattern formation in EUV-lithography photoresists: towards ultimate resolution limits" (MM2ULTIM), with Project No. 17966, of the research programme "High Tech Systems and Materials" of the Netherlands Organization for Scientific Research (NWO). The project is jointly financed by NWO and Simbeyond B.V. The authors thank prof. Fred Brouwer (University of Amsterdam and ARCNL), dr. Sonia Castellanos-Ortega (Inpria), dr. Harm van Eersel (Simbeyond), dr. Stefano Gottardi (Simbeyond), dr. Kees Hagen (TU-Delft) dr. Frank de Jong (Thermofisher Scientific), dr. Peter Kraus (ARCNL), prof. Sense Jan van der Molen (Leiden University), dr. Danilo De Simone (IMEC) and dr. Engin Torun (Simbeyond) and for useful discussions.

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