Extreme ultraviolet (EUV) lithography faces significant challenges in designing suitable resist materials that can provide adequate precision, while maintaining economically viable throughput. These challenges in resist materials have led to printing failures and high roughness in EUV patterns, compromising the performance of semiconductor devices. Integrating directed self-assembly (DSA) of block copolymers (BCPs) with EUV lithography offers a promising solution because, while the BCPs register to the EUV-defined chemical guiding pattern, the thermodynamically determined structures of the BCPs automatically rectify defects and roughness in the EUV pattern. Despite the superior resolution of metal-oxide EUV resists (MORs), their application to DSA is limited by the difficulty in converting them into chemical patterns that allow effective transfer of the rectified patterns of DSA films into inorganic materials. To address this challenge, this study introduces a novel strategy for fabricating chemical patterns using hydrogen silsesquioxane (HSQ), a high-resolution negative tone inorganic resist, as a model system for MORs. Initially, a sacrificial Cr pattern is generated from HSQ patterns via reactive ion etching. The sacrificial Cr pattern is converted into a chemical pattern by first grafting a water-soluble polyethylene oxide brush onto the substrate, then wet etching the Cr, and finally grafting nonpolar polystyrene brushes. Assembling polystyrene-block-poly(methyl methacrylate) on these patterns results in structures oriented and registered with the underlying pattern, achieving 24 nm full-pitch resolutions. This approach has the potential to integrate MOR patterns into the DSA process, thereby enabling the generation of high-quality sub-10 nm patterns with high-χ BCPs.

1.
J.
van Schoot
et al,
Proc. SPIE
11323
,
1132307
(
2020
).
2.
O.
Versolato
,
J.
Sheil
,
S.
Witte
,
W.
Ubachs
, and
R.
Hoekstra
,
J. Opt.
24
,
054014
(
2022
).
3.
H. J.
Levinson
,
Jpn. J. Appl. Phys.
61
,
SD0803
(
2022
).
4.
H.
Tang
,
J. C.
Shearer
,
L. L.
Cheong
,
N. A.
Saulnier
,
S. A.
Sieg
,
K.
Petrillo
,
A.
Metz
, and
J. C.
Arnold
,
J. Photopolym. Sci. Technol.
28
,
13
(
2015
).
5.
C.
Bencher
,
Y.
Chen
,
H.
Dai
,
W.
Montgomery
, and
L.
Huli
,
Proc. SPIE
6924
,
69244E
(
2008
).
6.
C. K.
Ober
,
H.
Xu
,
V.
Kosma
,
Kazunori
Sakai
, and
E. P.
Giannelis
,
Proc. SPIE
10583
,
1058306
(
2018
).
7.
S.
Kruger
,
C.
Higgins
,
C.
Gallatin
, and
R.
Brainard
,
J. Photopolym. Sci. Technol.
24
,
143
(
2011
).
8.
G. M.
Gallatin
,
P.
Naulleau
, and
R.
Brainard
,
Proc. SPIE
6519
,
651911
(
2007
).
9.
C.
Higgins
,
A.
Antohe
,
G.
Denbeaux
,
S.
Kruger
,
J.
Georger
, and
R.
Brainard
,
Proc. SPIE
7271
,
727147
(
2009
).
10.
R.
Gronheid
,
A. V.
Pret
,
B.
Rathsack
,
J.
Hooge
,
S.
Scheer
,
K.
Nafus
,
H.
Shite
, and
J.
Kitano
,
Proc. SPIE
7639
,
76390M
(
2010
).
11.
E. W.
Edwards
,
M.
Müller
,
M. P.
Stoykovich
,
H. H.
Solak
,
J. J.
de Pablo
, and
P. F.
Nealey
,
Macromolecules
40
,
90
(
2007
).
12.
M. P.
Stoykovich
,
K. C.
Daoulas
,
M.
Müller
,
H.
Kang
,
J. J.
de Pablo
, and
P. F.
Nealey
,
Macromolecules
43
,
2334
(
2010
).
13.
S.
Ji
,
L.
Wan
,
C.-C.
Liu
, and
P. F.
Nealey
,
Prog. Polym. Sci.
54
,
76
(
2016
).
14.
S. M.
Park
,
M. P.
Stoykovich
,
R.
Ruiz
,
Y.
Zhang
,
C. T.
Black
, and
P. F.
Nealey
,
Adv. Mater.
19
,
607
(
2007
).
15.
M. W.
Matsen
and
F. S.
Bates
,
Macromolecules
29
,
1091
(
1996
).
16.
A.
Semenov
,
Macromolecules
26
,
6617
(
1993
).
17.
L.
Verstraete
.,
Proc. SPIE
12497
,
124970I
(
2023
).
18.
R.
Ruiz
,
H.
Kang
,
F. A.
Detcheverry
,
E.
Dobisz
,
D. S.
Kercher
,
T. R.
Albrecht
,
J. J.
de Pablo
, and
P. F.
Nealey
,
Science
321
,
936
(
2008
).
19.
L.
Verstraete
,
H. S.
Suh
,
J.
Van Bel
,
B.-U.
Bak
,
S. E.
Kim
,
R.
Vallat
,
P.
Bezard
,
M.
Beggiato
, and
C.
Beral
,
Proc. SPIE
12956
,
129560G
(
2024
).
20.
F.
Gstrein
,
Proc. SPIE
11610
,
116100J
(
2021
).
21.
L.
Wan
,
R.
Ruiz
,
H.
Gao
,
K. C.
Patel
,
T. R.
Albrecht
,
J.
Yin
,
J.
Kim
,
Y.
Cao
, and
G.
Lin
,
ACS Nano
9
,
7506
(
2015
).
22.
H.
Tsai
.,
Proc. SPIE
9779
,
977910
(
2016
).
24.
J.
Wandell
,
K.
Gorman
,
B.
Alperson
,
D.
Baskaran
,
M. S.
Rahman
,
J.
Kim
,
S.
Michlik
,
Y.
Her
, and
S.
Miyazaki
,
Proc. SPIE
12956
,
129560F
(
2024
).
25.
S.
Ouk Kim
,
H. H.
Solak
,
M. P.
Stoykovich
,
N. J.
Ferrier
,
J. J.
De Pablo
, and
P. F.
Nealey
,
Nature
424
,
411
(
2003
).
26.
E. W.
Edwards
,
M. F.
Montague
,
H. H.
Solak
,
C. J.
Hawker
, and
P. F.
Nealey
,
Adv. Mater.
16
,
1315
(
2004
).
27.
C.-C.
Liu
,
E.
Han
,
M. S.
Onses
,
C. J.
Thode
,
S.
Ji
,
P.
Gopalan
, and
P. F.
Nealey
,
Macromolecules
44
,
1876
(
2011
).
28.
C.-C.
Liu
et al,
Macromolecules
46
,
1415
(
2013
).
29.
L.
Li
,
X.
Liu
,
S.
Pal
,
S.
Wang
,
C. K.
Ober
, and
E. P.
Giannelis
,
Chem. Soc. Rev.
46
,
4855
(
2017
).
30.
C. K.
Ober
,
F.
Käfer
, and
C.
Yuan
,
Polymer
280
,
126020
(
2023
).
31.
J.
Stowers
.,
Proc. SPIE
9779
,
977904
(
2016
).
32.
E.
Buitrago
,
R.
Fallica
,
D.
Fan
,
T. S.
Kulmala
,
M.
Vockenhuber
, and
Y.
Ekinci
,
Microelectron. Eng.
155
,
44
(
2016
).
33.
S.
Enomoto
,
K.
Machida
,
M.
Naito
, and
T.
Kozawa
,
Proc. SPIE
12292
,
122920D
(
2022
).
34.
C. D.
Needham
,
U.
Welling
,
A.
Narasimhan
,
P.
De Schepper
,
L.
McQuade
,
M.
Kocsis
,
L. S.
Melvin
III
,
J.
Stowers
, and
S. T.
Meyers
,
Proc. SPIE
12957
,
129571B
(
2024
).
35.
M. J.
Maher
et al,
ACS Appl. Mater. Interfaces
7
,
3323
(
2015
).
36.
H. S.
Suh
,
L.
Verstraete
,
J.
Van Bel
,
P.
Bézard
,
G.
Mannaert
,
J. U.
Lee
,
S.
Wang
,
I.
Pollentier
, and
A.
Rathore
,
Proc. SPIE PC12054
,
PC1205402
(
2022
).
37.
M.
Suzuki
.,
Proc. SPIE
12498
,
1249813
(
2023
).
38.
C.-C.
Liu
,
P. F.
Nealey
,
Y.-H.
Ting
, and
A. E.
Wendt
,
J. Vac. Sci. Technol. B
25
,
1963
(
2007
).
39.
T.
Thurn-Albrecht
,
R.
Steiner
,
J.
DeRouchey
,
C. M.
Stafford
,
E.
Huang
,
M.
Bal
,
M.
Tuominen
,
C. J.
Hawker
, and
T. P.
Russell
,
Adv. Mater.
12
,
787
(
2000
).
40.
Y.-C.
Tseng
,
Q.
Peng
,
L. E.
Ocola
,
J. W.
Elam
, and
S. B.
Darling
,
J. Phys. Chem. C
115
,
17725
(
2011
).
41.
Q.
Peng
,
Y.-C.
Tseng
,
S. B.
Darling
, and
J. W.
Elam
,
ACS Nano
5
,
4600
(
2011
).
42.
E.
Drockenmuller
,
L. Y. T.
Li
,
D. Y.
Ryu
,
E.
Harth
,
T. P.
Russell
,
H. C.
Kim
, and
C. J.
Hawker
,
J. Polym. Sci. Part A Polym. Chem.
43
,
1028
(
2005
).
43.
F.
Aydinoglu
,
H.
Yamada
,
R. K.
Dey
, and
B.
Cui
,
Langmuir
33
,
4981
(
2017
).
44.
R. K.
Dey
and
B.
Cui
,
Nanotechnology
24
,
245302
(
2013
).
45.
M.
Mao
,
F.
Lazzarino
,
P.
De Schepper
,
D.
De Simone
,
D.
Piumi
,
V.
Luong
,
F.
Yamashita
,
M.
Kocsis
, and
K.
Kumar
,
Proc. SPIE
10146
,
101460I
(
2017
).
46.
M.
Mohammad
,
S.
Dew
,
S.
Evoy
, and
M.
Stepanova
,
Microelectron. Eng.
88
,
2338
(
2011
).
47.
Y.
Ekinci
,
H. H.
Solak
,
C.
Padeste
,
J.
Gobrecht
,
M. P.
Stoykovich
, and
P. F.
Nealey
,
Microelectron. Eng.
84
,
700
(
2007
).
48.
T. P.
Russell
,
G.
Coulon
,
V.
Deline
, and
D.
Miller
,
Macromolecules
22
,
4600
(
1989
).
49.
H.
Ito
,
T. P.
Russell
, and
G.
Wignall
,
Macromolecules
20
,
2213
(
1987
).
50.
L.
Wan
,
R.
Ruiz
,
H.
Gao
, and
T. R.
Albrecht
,
ACS Nano
11
,
7666
(
2017
).
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