Higher-order lithography: Double-deprotected chemically amplified photoresists (DD-CAMP)

Deanna Soucie; William Earley; Kenji Hosoi; Arata Takahashi; Takashi Aoki; Brian Cardineau; Koichi Miyauchi; Robert Brainard

doi:10.2494/photopolymer.30.351

Higher-order lithography: Double-deprotected chemically amplified photoresists (DD-CAMP)

Deanna Soucie
, William Earley
, Kenji Hosoi
, Arata Takahashi
, Takashi Aoki
, Brian Cardineau
, Koichi Miyauchi
, Robert Brainard

Nanoscale Science and Engineering

University at Albany

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

The synthesis and lithographic evaluation of 193-nm and EUV photoresists that utilize a higher-order reaction mechanism of deprotection is presented. Unique polymers utilize novel blocking groups that require two acid-catalyzed steps to be removed. When these steps occur with comparable reaction rates, the overall reaction should be higher order (≤ 1.85). The LWR of these resists is plotted against PEB time for a variety of compounds to acquire insight into the effectiveness of the proposed higher-order mechanisms. Evidence acquired during testing of these novel photoresist materials supports the conclusion that higher-order reaction kinetics leads to improved LWR vs. control resists.

Original language	English
Pages (from-to)	351-359
Number of pages	9
Journal	Journal of Photopolymer Science and Technology
Volume	30
Issue number	3
DOIs	https://doi.org/10.2494/photopolymer.30.351
State	Published - 2017

Keywords

193 nm
DD-CAMP
EUV
Higher order
Kinetics
Photoresist

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10.2494/photopolymer.30.351

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title = "Higher-order lithography: Double-deprotected chemically amplified photoresists (DD-CAMP)",

abstract = "The synthesis and lithographic evaluation of 193-nm and EUV photoresists that utilize a higher-order reaction mechanism of deprotection is presented. Unique polymers utilize novel blocking groups that require two acid-catalyzed steps to be removed. When these steps occur with comparable reaction rates, the overall reaction should be higher order (≤ 1.85). The LWR of these resists is plotted against PEB time for a variety of compounds to acquire insight into the effectiveness of the proposed higher-order mechanisms. Evidence acquired during testing of these novel photoresist materials supports the conclusion that higher-order reaction kinetics leads to improved LWR vs. control resists.",

keywords = "193 nm, DD-CAMP, EUV, Higher order, Kinetics, Photoresist",

author = "Deanna Soucie and William Earley and Kenji Hosoi and Arata Takahashi and Takashi Aoki and Brian Cardineau and Koichi Miyauchi and Robert Brainard",

year = "2017",

doi = "10.2494/photopolymer.30.351",

language = "English",

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pages = "351--359",

journal = "Journal of Photopolymer Science and Technology",

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TY - JOUR

T1 - Higher-order lithography

T2 - Double-deprotected chemically amplified photoresists (DD-CAMP)

AU - Soucie, Deanna

AU - Earley, William

AU - Hosoi, Kenji

AU - Takahashi, Arata

AU - Aoki, Takashi

AU - Cardineau, Brian

AU - Miyauchi, Koichi

AU - Brainard, Robert

PY - 2017

Y1 - 2017

N2 - The synthesis and lithographic evaluation of 193-nm and EUV photoresists that utilize a higher-order reaction mechanism of deprotection is presented. Unique polymers utilize novel blocking groups that require two acid-catalyzed steps to be removed. When these steps occur with comparable reaction rates, the overall reaction should be higher order (≤ 1.85). The LWR of these resists is plotted against PEB time for a variety of compounds to acquire insight into the effectiveness of the proposed higher-order mechanisms. Evidence acquired during testing of these novel photoresist materials supports the conclusion that higher-order reaction kinetics leads to improved LWR vs. control resists.

AB - The synthesis and lithographic evaluation of 193-nm and EUV photoresists that utilize a higher-order reaction mechanism of deprotection is presented. Unique polymers utilize novel blocking groups that require two acid-catalyzed steps to be removed. When these steps occur with comparable reaction rates, the overall reaction should be higher order (≤ 1.85). The LWR of these resists is plotted against PEB time for a variety of compounds to acquire insight into the effectiveness of the proposed higher-order mechanisms. Evidence acquired during testing of these novel photoresist materials supports the conclusion that higher-order reaction kinetics leads to improved LWR vs. control resists.

KW - 193 nm

KW - DD-CAMP

KW - EUV

KW - Higher order

KW - Kinetics

KW - Photoresist

UR - https://www.scopus.com/pages/publications/85027250162

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DO - 10.2494/photopolymer.30.351

M3 - Article

SN - 0914-9244

VL - 30

SP - 351

EP - 359

JO - Journal of Photopolymer Science and Technology

JF - Journal of Photopolymer Science and Technology

IS - 3

ER -

Higher-order lithography: Double-deprotected chemically amplified photoresists (DD-CAMP)

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