TY - JOUR
T1 - Stemless InSb nanowire networks and nanoflakes grown on InP
AU - Rossi, Marco
AU - van Schijndel, Teun A.J.
AU - Lueb, Pim
AU - Badawy, Ghada
AU - Jung, Jason
AU - Peeters, Wouter H.J.
AU - Kölling, Sebastian
AU - Moutanabbir, Oussama
AU - Verheijen, Marcel A.
AU - Bakkers, Erik P.A.M.
PY - 2024/10/7
Y1 - 2024/10/7
N2 - Among the experimental realization of fault-tolerant topological circuits are interconnecting nanowires with minimal disorder. Out-of-plane indium antimonide (InSb) nanowire networks formed by merging are potential candidates. Yet, their growth requires a foreign material stem usually made of InP-InAs. This stem imposes limitations, which include restricting the size of the nanowire network, inducing disorder through grain boundaries and impurity incorporation. Here, we omit the stem allowing for the growth of stemless InSb nanowire networks on an InP substrate. To enable the growth without the stem, we show that a preconditioning step using arsine (AsH3) is required before InSb growth. High-yield of stemless nanowire growth is achieved by patterning the substrate with a selective-area mask with nanohole cavities, containing restricted gold droplets from which nanowires originate. Interestingly, these nanowires are bent, posing challenges for the synthesis of interconnecting nanowire networks due to merging failure. We attribute this bending to the non-homogeneous incorporation of arsenic impurities in the InSb nanowires and the interposed lattice-mismatch. By tuning the growth parameters, we can mitigate the bending, yielding large and single crystalline InSb nanowire networks and nanoflakes. The improved size and crystal quality of these nanostructures broaden the potential of this technique for fabricating advanced quantum devices.
AB - Among the experimental realization of fault-tolerant topological circuits are interconnecting nanowires with minimal disorder. Out-of-plane indium antimonide (InSb) nanowire networks formed by merging are potential candidates. Yet, their growth requires a foreign material stem usually made of InP-InAs. This stem imposes limitations, which include restricting the size of the nanowire network, inducing disorder through grain boundaries and impurity incorporation. Here, we omit the stem allowing for the growth of stemless InSb nanowire networks on an InP substrate. To enable the growth without the stem, we show that a preconditioning step using arsine (AsH3) is required before InSb growth. High-yield of stemless nanowire growth is achieved by patterning the substrate with a selective-area mask with nanohole cavities, containing restricted gold droplets from which nanowires originate. Interestingly, these nanowires are bent, posing challenges for the synthesis of interconnecting nanowire networks due to merging failure. We attribute this bending to the non-homogeneous incorporation of arsenic impurities in the InSb nanowires and the interposed lattice-mismatch. By tuning the growth parameters, we can mitigate the bending, yielding large and single crystalline InSb nanowire networks and nanoflakes. The improved size and crystal quality of these nanostructures broaden the potential of this technique for fabricating advanced quantum devices.
KW - bending
KW - InSb
KW - metal organic vapor phase epitaxy
KW - nanoflakes
KW - nanowires
UR - http://www.scopus.com/inward/record.url?scp=85199497044&partnerID=8YFLogxK
U2 - 10.1088/1361-6528/ad61ef
DO - 10.1088/1361-6528/ad61ef
M3 - Article
C2 - 38991513
AN - SCOPUS:85199497044
SN - 0957-4484
VL - 35
JO - Nanotechnology
JF - Nanotechnology
IS - 41
M1 - 415602
ER -