Your search keyword '"Joonmyung Choi"' showing total 2 results

1. Theoretical modeling of PEB procedure on EUV resist using FDM formulation

Author

Junghwan Moon, Muyoung Kim, Maenghyo Cho, Hee-Bom Kim, Byunghoon Lee, Joonmyung Choi, and Changyoung Jeong

Subjects

Reaction rate, Materials science, Reaction rate constant, Resist, Semiconductor device fabrication, Extreme ultraviolet lithography, Mechanics, Photoresist, Diffusion (business), Multiscale modeling

Abstract

Semiconductor manufacturing industry has reduced the size of wafer for enhanced productivity and performance, and Extreme Ultraviolet (EUV) light source is considered as a promising solution for downsizing. A series of EUV lithography procedures contain complex photo-chemical reaction on photoresist, and it causes technical difficulties on constructing theoretical framework which facilitates rigorous investigation of underlying mechanism. Thus, we formulated finite difference method (FDM) model of post exposure bake (PEB) process on positive chemically amplified resist (CAR), and it involved acid diffusion coupled-deprotection reaction. The model is based on Fick’s second law and first-order chemical reaction rate law for diffusion and deprotection, respectively. Two kinetic parameters, diffusion coefficient of acid and rate constant of deprotection, which were obtained by experiment and atomic scale simulation were applied to the model. As a result, we obtained time evolutional protecting ratio of each functional group in resist monomer which can be used to predict resulting polymer morphology after overall chemical reactions. This achievement will be the cornerstone of multiscale modeling which provides fundamental understanding on important factors for EUV performance and rational design of the next-generation photoresist.

Published

2018

2. Computational approach on PEB process in EUV resist: multi-scale simulation

Author

Byunghoon Lee, Joonmyung Choi, Junghwan Moon, Changyoung Jeong, Muyoung Kim, Hee-Bom Kim, and Maenghyo Cho

Subjects

010302 applied physics, Materials science, 010304 chemical physics, business.industry, Extreme ultraviolet lithography, Nanotechnology, Material Design, Photoresist, 01 natural sciences, Chemical reaction, Molecular dynamics, Semiconductor, Resist, 0103 physical sciences, Optoelectronics, Density functional theory, business

Abstract

For decades, downsizing has been a key issue for high performance and low cost of semiconductor, and extreme ultraviolet lithography is one of the promising candidates to achieve the goal. As a predominant process in extreme ultraviolet lithography on determining resolution and sensitivity, post exposure bake has been mainly studied by experimental groups, but development of its photoresist is at the breaking point because of the lack of unveiled mechanism during the process. Herein, we provide theoretical approach to investigate underlying mechanism on the post exposure bake process in chemically amplified resist, and it covers three important reactions during the process: acid generation by photo-acid generator dissociation, acid diffusion, and deprotection. Density functional theory calculation (quantum mechanical simulation) was conducted to quantitatively predict activation energy and probability of the chemical reactions, and they were applied to molecular dynamics simulation for constructing reliable computational model. Then, overall chemical reactions were simulated in the molecular dynamics unit cell, and final configuration of the photoresist was used to predict the line edge roughness. The presented multiscale model unifies the phenomena of both quantum and atomic scales during the post exposure bake process, and it will be helpful to understand critical factors affecting the performance of the resulting photoresist and design the next-generation material.

Published

2017