Template-Assisted Scalable Nanowire Networks

Topological qubits based on Majorana Fermions have the potential to revolutionize the emerging field of quantum computing by making information processing significantly more robust to decoherence. Nanowires are a promising medium for hosting these kinds of qubits, though branched nanowires are neede...

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Detalles Bibliográficos
Autores: Friedl, Martin, Cerveny, Kris, Weigele, Pirmin, Tütüncüoglu, Gözde, Martí-Sánchez, Sara|||0000-0003-4283-1489, Huang, Chunyi, Patlatiuk, Taras, Potts, Heidi A., Sun, Zhiyuan|||0000-0003-3981-9083, Hill, Megan O.|||0000-0002-7663-7986, Güniat, Lucas|||0000-0001-7883-4433, Kim, Wonjong, Zamani, Mahdi|||0000-0003-0750-2938, Dubrovskii, Vladimir G.|||0000-0003-2088-7158, Arbiol i Cobos, Jordi|||0000-0002-0695-1726, Lauhon, Lincoln J.|||0000-0001-6046-3304, Zumbühl, Dominik M., Fontcuberta i Morral, Anna|||0000-0002-5070-2196
Tipo de recurso: artículo
Fecha de publicación:2018
País:España
Institución:Universitat Autònoma de Barcelona
Repositorio:Dipòsit Digital de Documents de la UAB
Idioma:inglés
OAI Identifier:oai:ddd.uab.cat:210993
Acceso en línea:https://ddd.uab.cat/record/210993
https://dx.doi.org/urn:doi:10.1021/acs.nanolett.8b00554
Access Level:acceso abierto
Palabra clave:Branched nanowires
Energy minimization
Lattice-mismatched
Magnetoconductance
Nanowire networks
Quantum Computing
Quantum transport
Templated growth
Descripción
Sumario:Topological qubits based on Majorana Fermions have the potential to revolutionize the emerging field of quantum computing by making information processing significantly more robust to decoherence. Nanowires are a promising medium for hosting these kinds of qubits, though branched nanowires are needed to perform qubit manipulations. Here we report a gold-free templated growth of III-V nanowires by molecular beam epitaxy using an approach that enables patternable and highly regular branched nanowire arrays on a far greater scale than what has been reported thus far. Our approach relies on the lattice-mismatched growth of InAs on top of defect-free GaAs nanomembranes yielding laterally oriented, low-defect InAs and InGaAs nanowires whose shapes are determined by surface and strain energy minimization. By controlling nanomembrane width and growth time, we demonstrate the formation of compositionally graded nanowires with cross-sections less than 50 nm. Scaling the nanowires below 20 nm leads to the formation of homogeneous InGaAs nanowires, which exhibit phase-coherent, quasi-1D quantum transport as shown by magnetoconductance measurements. These results are an important advance toward scalable topological quantum computing.