Advanced EUV mask and imaging modeling

Abstract. The exploration and optimization of image formation in partially coherent EUV projection systems with complex source shapes requires flexible, accurate, and efficient simulation models. This paper reviews advanced mask diffraction and imaging models for the highly accurate and fast simulation of EUV lithography systems, addressing important aspects of the current technical developments. The simulation of light diffraction from the mask employs an extended rigorous coupled wave analysis (RCWA) approach, which is optimized for EUV applications. In order to be able to deal with current EUV simulation requirements, several additional models are included in the extended RCWA approach: a field decomposition and a field stitching technique enable the simulation of larger complex structured mask areas. An EUV multilayer defect model including a database approach makes the fast and fully rigorous defect simulation and defect repair simulation possible. A hybrid mask simulation approach combining real and ideal mask parts allows the detailed investigation of the origin of different mask 3-D effects. The image computation is done with a fully vectorial Abbe-based approach. Arbitrary illumination and polarization schemes and adapted rigorous mask simulations guarantee a high accuracy. A fully vectorial sampling-free description of the pupil with Zernikes and Jones pupils and an optimized representation of the diffraction spectrum enable the computation of high-resolution images with high accuracy and short simulation times. A new pellicle model supports the simulation of arbitrary membrane stacks, pellicle distortions, and particles/defects on top of the pellicle. Finally, an extension for highly accurate anamorphic imaging simulations is included. The application of the models is demonstrated by typical use cases.

[1]  E. Hendrickx,et al.  Physical resist models and their calibration: their readiness for accurate EUV lithography simulation , 2010, Advanced Lithography.

[2]  Iwao Nishiyama,et al.  Quantifying EUV imaging tolerances for the 70-, 50-, 35-nm modes through rigorous aerial image simulations , 2001, SPIE Advanced Lithography.

[3]  Jean-Pierre Berenger,et al.  A perfectly matched layer for the absorption of electromagnetic waves , 1994 .

[4]  Andreas Erdmann,et al.  Simulation of extreme ultraviolet masks with defective multilayers , 2003, Photomask Japan.

[5]  Joerg Bischoff,et al.  Scatterometry modeling for gratings with roughness and irregularities , 2016, SPIE Advanced Lithography.

[6]  Peter Evanschitzky,et al.  Extended Abbe approach for fast and accurate lithography imaging simulations , 2009, European Mask and Lithography Conference.

[7]  Vicky Philipsen,et al.  Reducing EUV mask 3D effects by alternative metal absorbers , 2017, Advanced Lithography.

[8]  Jo Finders,et al.  Illumination pupil optimization in 0.33-NA extreme ultraviolet lithography by intensity balancing for semi-isolated dark field two-bar M1 building blocks , 2016 .

[9]  Thomas K. Gaylord,et al.  Stable implementation of the rigorous coupled-wave analysis for surface-relief gratings: enhanced transmittance matrix approach , 1995 .

[10]  Kevin D. Lucas,et al.  Efficient and rigorous three-dimensional model for optical lithography simulation , 1996 .

[11]  Stephen Hsu,et al.  EUV resolution enhancement techniques (RETs) for k1 0.4 and below , 2015, Advanced Lithography.

[12]  Feng Shao,et al.  Lithography simulation: modeling techniques and selected applications , 2009, Optical Metrology.

[13]  H. Hopkins On the diffraction theory of optical images , 1953, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[14]  Peter De Bisschop,et al.  Validity of the Hopkins approximation in simulations of hyper-NA (NA>1) line-space structures for an attenuated PSM mask , 2006, SPIE Advanced Lithography.

[15]  Feng Shao,et al.  Simulation of larger mask areas using the waveguide method with fast decomposition technique , 2007, SPIE Photomask Technology.

[16]  Martin Burkhardt,et al.  Best focus shift mechanism for thick masks , 2015, Advanced Lithography.

[17]  Andrew R. Neureuther,et al.  Simplified model for absorber feature transmissions on EUV masks , 2006, SPIE Photomask Technology.

[18]  M. Certain computational aspects of vector diffraction problems , 2002 .

[19]  Chandraprakash Chindam Fourier Modal Method and Its Applications in Computational Nanophotonics , 2012 .

[20]  Michael C. Lam,et al.  Flare in extreme ultraviolet lithography: metrology, out-of-band radiation, fractal point-spread function, and flare map calibration , 2009 .

[21]  Andrew R. Neureuther,et al.  Fast simulation methods and modeling for extreme ultraviolet masks with buried defects , 2009 .

[22]  M R Taghizadeh,et al.  Analysis of gratings with large periods and small feature sizes by stitching of the electromagnetic field. , 1996, Optics letters.

[23]  Lifeng Li,et al.  Use of Fourier series in the analysis of discontinuous periodic structures , 1996 .

[24]  Khanh Nguyen,et al.  Effects of absorber topography and multilayer coating defects on reflective masks for soft x-ray/EUV projection lithography , 1993, Advanced Lithography.

[25]  A. Hawryluk,et al.  Soft x‐ray projection lithography using an x‐ray reduction camera , 1988 .

[26]  Vicky Philipsen,et al.  Characterization and mitigation of 3D mask effects in extreme ultraviolet lithography , 2017 .

[27]  C. Mack Analytic form for the power spectral density in one, two, and three dimensions , 2011 .

[28]  Andreas Erdmann,et al.  Fast near field simulation of optical and EUV masks using the waveguide method , 2007, European Mask and Lithography Conference.

[29]  Guido Schiffelers,et al.  NXE:3300B platform: imaging applications for Logic and DRAM , 2013, Other Conferences.

[30]  Feng Shao,et al.  Efficient simulation of extreme ultraviolet multilayer defects with rigorous data base approach , 2013 .

[31]  Peter Evanschitzky,et al.  Three dimensional EUV simulations: a new mask near field and imaging simulation system , 2005, SPIE Photomask Technology.

[32]  Daniel Wintz,et al.  Photon flux requirements for extreme ultraviolet reticle imaging in the 22- and 16-nm nodes , 2010 .

[33]  Andrew R. Neureuther,et al.  Simplified models for edge transitions in rigorous mask modeling , 2001, SPIE Advanced Lithography.

[34]  Yunfei Deng,et al.  Extreme ultraviolet mask defect simulation: Low-profile defects , 2000 .

[35]  Ronald L. Gordon,et al.  Mask topography simulation for EUV lithography , 1999, Advanced Lithography.

[36]  A. Wong Optical Imaging in Projection Microlithography , 2005 .

[37]  Zhengrong Zhu,et al.  METROPOLE-3D: a three-dimensional electromagnetic field simulator for EUV masks under oblique illumination , 2003, SPIE Photomask Technology.

[38]  Patrick Schiavone,et al.  Rigorous electromagnetic simulation of EUV masks: influence of the absorber properties , 2001 .

[39]  Tsuneo Terasawa,et al.  Simulation of Multilayer Defects in Extreme Ultraviolet Masks , 2001 .

[40]  Stephen Hsu,et al.  Application of EUV resolution enhancement techniques (RET) to optimize and extend single exposure bi-directional patterning for 7nm and beyond logic designs , 2016, SPIE Advanced Lithography.

[41]  Feng Shao,et al.  Fast rigorous simulation of mask diffraction using the waveguide method with parallelized decomposition technique , 2008, European Mask and Lithography Conference.

[42]  Feng Shao,et al.  Efficient simulation of three-dimensional EUV masks for rigorous source mask optimization and mask induced imaging artifact analysis , 2010, European Mask and Lithography Conference.

[43]  Pei-yang Yan,et al.  Understanding Bossung curve asymmetry and focus shift effect in EUV lithography , 2002, SPIE Photomask Technology.