A process sequence enabling the large-area fabrication of nanopillar-patterned semiconductor templates for selective-area heteroepitaxy is developed. Herein, the nanopillar tops surrounded by a SiNx mask film serve as nanoscale growth areas. The molecular beam epitaxial growth of InAs on such patterned GaAsA templates is investigated by means of electron microscopy. It is found that defect-free nanoscale InAs islands grow selectively on the nanopillar tops at a substrate temperature of 425 °C. High-angle annular dark-field scanning transmission electron microscopy imaging reveals that for a growth temperature of 400 °C, the InAs islands show a tendency to form wurtzite phase arms extending along the lateral directions from the central zinc blende region of the islands. This is ascribed to a temporary self-catalyzed vapor–liquid–solid growth on B facets, which leads to a kinetically induced preference for the nucleation of the wurtzite phase driven by the local, instantaneous V/III ratio, and to a concomitant reduction of surface energy of the nanoscale diameter arms.
REFERENCES
1.
S.
Lourdudoss
, Curr. Opin. Solid State Mater. Sci.
16
, 91
(2012
). 2.
T.
Riedl
and J. K. N.
Lindner
, in Nanoscaled Films and Layers
, edited by L.
Nánai
(IntechOpen Publishers
, Rijeka
, 2017
), p. 83
.3.
B.
Kunert
, Y.
Mols
, M.
Baryshinskova
, N.
Waldron
, A.
Schulze
, and R.
Langer
, Semicond. Sci. Technol.
33
, 093002
(2018
). 4.
Y.
Du
, B.
Xu
, G.
Wang
, Y.
Miao
, B.
Li
, Z.
Kong
, Y.
Dong
, W.
Wang
, and H. H.
Radamson
, Nanomaterials
12
, 741
(2022
). 5.
V. S.
Kunnathully
, T.
Riedl
, A.
Trapp
, T.
Langer
, D.
Reuter
, and J. K. N.
Lindner
, J. Cryst. Growth
537
, 125597
(2020
). 6.
H.
Paetzelt
, V.
Gottschalch
, J.
Bauer
, G.
Benndorf
, and G.
Wagner
, J. Cryst. Growth
310
, 5093
(2008
). 7.
K.
Tomioka
, K.
Ikejiri
, T.
Tanaka
, J.
Motohisa
, S.
Hara
, K.
Hiruma
, and T.
Fukui
, J. Mater. Res.
26
, 2127
(2011
). 8.
S.
Plissard
, K. A.
Dick
, G.
Larrieu
, S.
Godey
, A.
Addad
, X.
Wallart
, and P.
Caroff
, Nanotechnology
21
, 385602
(2010
). 9.
M.
Fahed
, L.
Desplanque
, D.
Troadec
, G.
Patriarche
, and X.
Wallert
, Nanotechnology
27
, 505301
(2016
). 10.
Z.-R.
Lv
, Z.-K.
Zhang
, X.-G.
Yang
, and T.
Yang
, Appl. Phys. Lett.
113
, 011105
(2018
). 11.
H.
Yoshikawa
, J.
Kwoen
, T.
Doe
, M.
Izumi
, S.
Iwamoto
, and Y.
Arakawa
, Electron. Lett.
54
, 1395
(2018
). 12.
M.
Egard
, S.
Johansson
, A.-C.
Johansson
, K.-M.
Persson
, A. W.
Dey
, B. M.
Borg
, C.
Thelander
, L.-E.
Wernersson
, and E.
Lind
, Nano Lett.
10
, 809
(2010
). 13.
G.
Niu
, G.
Capellini
, M. A.
Schubert
, T.
Niermann
, P.
Zaumseil
, J.
Katzer
, H.-M.
Krause
, O.
Skibitzki
, M.
Lehmann
, Y.-H.
Xie
, H.
von Känel
, and T.
Schroeder
, Sci. Rep.
6
, 22709
(2016
). 14.
I.
Prieto
, R.
Kozak
, O.
Skibitzki
, M. D.
Rossell
, P.
Zaumseil
, G.
Capellini
, E.
Gini
, K.
Kunze
, Y. A. R.
Dasilva
, R.
Erni
, T.
Schroeder
, and H.
von Känel
, Nanotechnology
28
, 135701
(2017
). 15.
O.
Skibitzki
, I.
Prieto
, R.
Kozak
, G.
Capellini
, P.
Zaumseil
, Y.
Arroyo Rojas Dasilva
, M. D.
Rossell
, R.
Erni
, H.
von Känel
, and T.
Schroeder
, Nanotechnology
28
, 135301
(2017
). 16.
G.
Kozlowski
, P.
Zaumseil
, M. A.
Schubert
, Y.
Yamamoto
, J.
Bauer
, J.
Matejova
, T.
Schulli
, B.
Tillack
, and T.
Schroeder
, Appl. Phys. Lett.
99
, 141901
(2011
). 17.
G.
Kozlowski
, P.
Zaumseil
, M. A.
Schubert
, Y.
Yamamoto
, J.
Bauer
, T. U.
Schülli
, B.
Tillack
, and T.
Schroeder
, Nanotechnol.
23
, 115704
(2012
). 18.
B. A.
Joyce
, D. D.
Vvedensky
, T. S.
Jones
, M.
Itoh
, G. R.
Bell
, and J. G.
Belk
, J. Cryst. Growth
201/202
, 106
(1999
). 19.
T.
Riedl
, V. S.
Kunnathully
, A.
Trapp
, T.
Langer
, D.
Reuter
, and J. K. N.
Lindner
, Phys. Rev. Mater.
4
, 014602
(2020
). 20.
J. C.
Hulteen
and R. P.
Van Duyne
, J. Vac. Sci. Technol. A
13
, 1553
(1995
). 21.
C.-W.
Kuo
, J.-Y.
Shiu
, P.
Chen
, and G. A.
Somorjai
, J. Phys. Chem. B
107
, 9950
(2003
). 22.
T.
Riedl
and J. K. N.
Lindner
, Phys. Status Solidi A
211
, 2871
(2014
). 23.
M. J.
Hÿtch
, E.
Snoeck
, and R.
Kilaas
, Ultramicroscopy
74
, 131
(1998
). 24.
See www.hremresearch.com/Eng/plugin/GPAEng.html for HREM Research Inc, GPA for DigitalMicrograph (2022).
25.
See www.gatan.com/products/tem-analysis/gatan-microscopy-suite-software for Gatan Inc., Gatan Microscopy Suite Software (2022).
26.
T.
Riedl
and J. K. N.
Lindner
, MRS Online Proc. Libr.
1664
, 7
(2014
). 27.
S. C.
Lee
and S.
Brueck
, Cryst. Growth Des.
16
, 3669
(2016
). 28.
P.
Caroff
, K. A.
Dick
, J.
Johansson
, M. E.
Messing
, K.
Deppert
, and L.
Samuelson
, Nat. Nanotechnol.
4
, 50
(2009
). 29.
M.
de la Mata
, C.
Magén
, P.
Caroff
, and J.
Arbiol
, Nano Lett.
14
, 6614
(2014
). 30.
M.
Zamani
, G.
Tütüncüoglu
, S.
Marti-Sanchez
, L.
Francaviglia
, L.
Güniat
, L.
Ghisalberti
, H.
Potts
, M.
Friedl
, E.
Markov
, W.
Kim
, J.-B.
Leran
, V. G.
Dubrovskii
, J.
Arbiol
, and A.
Fontcuberta i Morral
, Nanoscale
10
, 17080
(2018
). 31.
T.
Akiyama
, K.
Sano
, K.
Nakamura
, and T.
Ito
, Jpn. J. Appl. Phys.
45
, L275
(2006
). 32.
A.
Biermanns
, E.
Dimakis
, A.
Davydok
, T.
Sasaki
, L.
Geelhaar
, M.
Takahasi
, and U.
Pietsch
, Nano Lett.
14
, 6878
(2014
). 33.
F.
Panciera
, Z.
Baraissov
, G.
Patriarche
, V. G.
Dubrovskii
, F.
Glas
, L.
Travers
, U.
Mirsaidov
, and J.-C.
Harmand
, Nano Lett.
20
, 1669
(2020
). 34.
T.
Dursap
, M.
Vettori
, C.
Botella
, P.
Regreny
, N.
Blanchard
, M.
Gendry
, N.
Chauvin
, M.
Bugnet
, A.
Danescu
, and J.
Penuelas
, Nanotechnology
32
, 155602
(2021
). 35.
X.
Yu
, H.
Wang
, J.
Lu
, J.
Zhao
, J.
Misuraca
, P.
Xiong
, and S.
von Molnár
, Nano Lett.
12
, 5436
(2012
). 36.
T.
Riedl
, V. S.
Kunnathully
, A.
Trapp
, T.
Langer
, D.
Reuter
, and J. K. N.
Lindner
, Adv. Mater. Interfaces
9
, 2102159
(2022
). © 2022 Author(s). Published under an exclusive license by AIP Publishing.
2022
Author(s)
You do not currently have access to this content.
