Chung-Hyun Ban scite author profile

Thermal and structural deformation of extreme-ultraviolet lithography (EUVL) masks during the exposure process may become important issues as these masks are subject to rigorous image placement and flatness requirements. The reflective masks used for EUVL absorb energy during exposure, and the temperature of the masks rises as a result. This can cause thermomechanical deformation that can reduce the pattern quality. The use of very thick low-thermal-expansion substrate materials (LTEMs) may reduce energy absorption, but they do not completely eliminate mask deformation. Therefore, it is necessary to predict and optimize the effects of energy transferred from the extreme-ultraviolet (EUV) light source and the resultant patterns of structured EUV masks with complex multilayers. Our study shows that heat accumulates in the masks as exposure progresses. It has been found that a higher absorber ratio (pattern density) applied to the patterning of EUV masks exacerbates the problem, especially in masks with more complex patterns.

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Line width roughness variation and printing failures caused by stochastic effect at extreme-ultraviolet exposure

Kang

Kim

Hur

et al. 2021

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Optimal phase shift mask and multilayer stack with the evaluation of imaging performance and process latitude in extreme ultraviolet high numerical aperture

Kang¹,

Park²,

Ban³

et al. 2021

Jpn. J. Appl. Phys.

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In high numerical aperture (NA) extreme ultraviolet lithography, which is used to implement a finer linewidth of 10 nm or lower, serious problems arise in patterning as the NA increases. To alleviate such problems, a thin absorber and a multilayer with good reflective efficiency and improved pattern quality are required. To develop an effective EUV photomask for the commercialization of high-NA systems, we determined the optimal ruthenium (Ru)/silicon (Si) multilayer structure using a phase-shift mask (PSM) absorber. A Ru/Si multilayer d R u = 2.2 nm , d S i = 4.7 nm using PSM as an absorber has a smaller best-focus range and placement error compared to the molybdenum (Mo)/silicon (Si) multilayer. At the same time, it provides improved image contrast, enabling more stable patterning. Even when the number of layers of the Ru/Si multilayer was reduced, it was confirmed that the reflectance efficiency and image quality were maintained.

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Lifetime estimation of extreme-ultraviolet pellicle at 500 W source power by thermal stress analysis

Park

Ban

Park

et al. 2017

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Chung-Hyun Ban

Possible extreme ultraviolet mask thermal deformation during exposure

Modeling of thermomechanical changes of extreme-ultraviolet mask and their dependence on absorber variation

Line width roughness variation and printing failures caused by stochastic effect at extreme-ultraviolet exposure

Optimal phase shift mask and multilayer stack with the evaluation of imaging performance and process latitude in extreme ultraviolet high numerical aperture

Lifetime estimation of extreme-ultraviolet pellicle at 500 W source power by thermal stress analysis

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