Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography

Yejin Ku; Hyungju Ahn; Jin Kyun Lee; Jiho Kim; Byeong Gyu Park; Sangsul Lee; Yu Ha Jang; Byung Jun Jung; Chawon Koh; Tsunehiro Nishi; Hyun Woo Kim

doi:10.1117/12.2658210

Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography

Yejin Ku, Hyungju Ahn, Jin Kyun Lee, Jiho Kim, Byeong Gyu Park, Sangsul Lee, Yu Ha Jang, Byung Jun Jung, Chawon Koh, Tsunehiro Nishi, Hyun Woo Kim

Department of Materials Science and Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Scopus citations

Abstract

Extreme UV (EUV) lithography is entering full-scale production of high-end IC chips. This transition gives researchers in academia and industry ample motivation to propose new chemistries that will contribute to alleviating the resolution-line edge roughness-sensitivity trade-off dilemma of EUV lithography. We also have a great interest in the radical chemistry of carbon-fluorine bonds working under EUV and have explored its applicability as a platform for implementing novel EUV resists. While it was checked that the chemical concept is viable by using fluorinated small molecules and polymers, it needed to be upgraded in terms of patterning resolution and sensitivity. Recently, we extended successfully the radical-based strategy to the tin-oxo nano cluster resist concept. Soluble fluorinated tin-oxo clusters could be prepared, and they were cast into thin films from a fluorous solution. When the thin film was exposed to EUV radiation, it lost solubility, resulting in the formation of negative-tone images. Under an EUV lithographic condition, the thin film could be tailored down to 10 nm or smaller sized features. In addition, their unique solubility in chemically orthogonal solvents also enabled the build-up of a bilayer structure composed of a non-fluorinated reactive polymer underlayer without curing. The stacked film structure was found to be helpful for the sensitivity improvement. These results propose another interesting EUV resist candidate possessing unique capabilities in thin film processing.

Original language	English
Title of host publication	Advances in Patterning Materials and Processes XL
Editors	Douglas Guerrero, Gilles R. Amblard
Publisher	SPIE
ISBN (Electronic)	9781510661035
DOIs	https://doi.org/10.1117/12.2658210
State	Published - 2023
Event	Advances in Patterning Materials and Processes XL 2023 - San Jose, United States Duration: 27 Feb 2023 → 1 Mar 2023

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	12498
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Advances in Patterning Materials and Processes XL 2023
Country/Territory	United States
City	San Jose
Period	27/02/23 → 1/03/23

Keywords

EUV resist
Extreme UV lithography
fluorinated tin-oxo cluster
fluorination
non-chemically amplified resist

Access to Document

10.1117/12.2658210

Cite this

Ku, Y., Ahn, H., Lee, J. K., Kim, J., Park, B. G., Lee, S., Jang, Y. H., Jung, B. J., Koh, C., Nishi, T., & Kim, H. W. (2023). Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography. In D. Guerrero, & G. R. Amblard (Eds.), Advances in Patterning Materials and Processes XL Article 1249816 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12498). SPIE. https://doi.org/10.1117/12.2658210

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title = "Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography",

abstract = "Extreme UV (EUV) lithography is entering full-scale production of high-end IC chips. This transition gives researchers in academia and industry ample motivation to propose new chemistries that will contribute to alleviating the resolution-line edge roughness-sensitivity trade-off dilemma of EUV lithography. We also have a great interest in the radical chemistry of carbon-fluorine bonds working under EUV and have explored its applicability as a platform for implementing novel EUV resists. While it was checked that the chemical concept is viable by using fluorinated small molecules and polymers, it needed to be upgraded in terms of patterning resolution and sensitivity. Recently, we extended successfully the radical-based strategy to the tin-oxo nano cluster resist concept. Soluble fluorinated tin-oxo clusters could be prepared, and they were cast into thin films from a fluorous solution. When the thin film was exposed to EUV radiation, it lost solubility, resulting in the formation of negative-tone images. Under an EUV lithographic condition, the thin film could be tailored down to 10 nm or smaller sized features. In addition, their unique solubility in chemically orthogonal solvents also enabled the build-up of a bilayer structure composed of a non-fluorinated reactive polymer underlayer without curing. The stacked film structure was found to be helpful for the sensitivity improvement. These results propose another interesting EUV resist candidate possessing unique capabilities in thin film processing.",

keywords = "EUV resist, Extreme UV lithography, fluorinated tin-oxo cluster, fluorination, non-chemically amplified resist",

author = "Yejin Ku and Hyungju Ahn and Lee, {Jin Kyun} and Jiho Kim and Park, {Byeong Gyu} and Sangsul Lee and Jang, {Yu Ha} and Jung, {Byung Jun} and Chawon Koh and Tsunehiro Nishi and Kim, {Hyun Woo}",

note = "Publisher Copyright: {\textcopyright} COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.; Advances in Patterning Materials and Processes XL 2023 ; Conference date: 27-02-2023 Through 01-03-2023",

year = "2023",

doi = "10.1117/12.2658210",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Douglas Guerrero and Amblard, {Gilles R.}",

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Ku, Y, Ahn, H, Lee, JK, Kim, J, Park, BG, Lee, S, Jang, YH, Jung, BJ, Koh, C, Nishi, T & Kim, HW 2023, Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography. in D Guerrero & GR Amblard (eds), Advances in Patterning Materials and Processes XL., 1249816, Proceedings of SPIE - The International Society for Optical Engineering, vol. 12498, SPIE, Advances in Patterning Materials and Processes XL 2023, San Jose, United States, 27/02/23. https://doi.org/10.1117/12.2658210

Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography. / Ku, Yejin; Ahn, Hyungju; Lee, Jin Kyun et al.
Advances in Patterning Materials and Processes XL. ed. / Douglas Guerrero; Gilles R. Amblard. SPIE, 2023. 1249816 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12498).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography

AU - Ku, Yejin

AU - Ahn, Hyungju

AU - Lee, Jin Kyun

AU - Kim, Jiho

AU - Park, Byeong Gyu

AU - Lee, Sangsul

AU - Jang, Yu Ha

AU - Jung, Byung Jun

AU - Koh, Chawon

AU - Nishi, Tsunehiro

AU - Kim, Hyun Woo

PY - 2023

Y1 - 2023

N2 - Extreme UV (EUV) lithography is entering full-scale production of high-end IC chips. This transition gives researchers in academia and industry ample motivation to propose new chemistries that will contribute to alleviating the resolution-line edge roughness-sensitivity trade-off dilemma of EUV lithography. We also have a great interest in the radical chemistry of carbon-fluorine bonds working under EUV and have explored its applicability as a platform for implementing novel EUV resists. While it was checked that the chemical concept is viable by using fluorinated small molecules and polymers, it needed to be upgraded in terms of patterning resolution and sensitivity. Recently, we extended successfully the radical-based strategy to the tin-oxo nano cluster resist concept. Soluble fluorinated tin-oxo clusters could be prepared, and they were cast into thin films from a fluorous solution. When the thin film was exposed to EUV radiation, it lost solubility, resulting in the formation of negative-tone images. Under an EUV lithographic condition, the thin film could be tailored down to 10 nm or smaller sized features. In addition, their unique solubility in chemically orthogonal solvents also enabled the build-up of a bilayer structure composed of a non-fluorinated reactive polymer underlayer without curing. The stacked film structure was found to be helpful for the sensitivity improvement. These results propose another interesting EUV resist candidate possessing unique capabilities in thin film processing.

AB - Extreme UV (EUV) lithography is entering full-scale production of high-end IC chips. This transition gives researchers in academia and industry ample motivation to propose new chemistries that will contribute to alleviating the resolution-line edge roughness-sensitivity trade-off dilemma of EUV lithography. We also have a great interest in the radical chemistry of carbon-fluorine bonds working under EUV and have explored its applicability as a platform for implementing novel EUV resists. While it was checked that the chemical concept is viable by using fluorinated small molecules and polymers, it needed to be upgraded in terms of patterning resolution and sensitivity. Recently, we extended successfully the radical-based strategy to the tin-oxo nano cluster resist concept. Soluble fluorinated tin-oxo clusters could be prepared, and they were cast into thin films from a fluorous solution. When the thin film was exposed to EUV radiation, it lost solubility, resulting in the formation of negative-tone images. Under an EUV lithographic condition, the thin film could be tailored down to 10 nm or smaller sized features. In addition, their unique solubility in chemically orthogonal solvents also enabled the build-up of a bilayer structure composed of a non-fluorinated reactive polymer underlayer without curing. The stacked film structure was found to be helpful for the sensitivity improvement. These results propose another interesting EUV resist candidate possessing unique capabilities in thin film processing.

KW - EUV resist

KW - Extreme UV lithography

KW - fluorinated tin-oxo cluster

KW - fluorination

KW - non-chemically amplified resist

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DO - 10.1117/12.2658210

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AN - SCOPUS:85163390345

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Advances in Patterning Materials and Processes XL

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A2 - Amblard, Gilles R.

PB - SPIE

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Y2 - 27 February 2023 through 1 March 2023

ER -

Fluoroalkylated tin-oxo nano clusters as resist candidates for extreme UV lithography

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