Andrea Iorio scite author profile

Semiconductor nanowires featuring strong spin-orbit interactions (SOI), represent a promising platform for a broad range of novel technologies, such as spintronic applications or topological quantum computation. However, experimental studies into the nature and the orientation of the SOI vector in these wires remain limited despite being of upmost importance. Typical devices feature the nanowires placed on top of a substrate which modifies the SOI vector and spoils the intrinsic symmetries of the system. In this work, we report experimental results on suspended InAs nanowires, in which the wire symmetries are fully preserved and clearly visible in transport measurements. Using a vectorial magnet, the non-trivial evolution of weak anti-localization (WAL) is tracked through all 3D space, and both the spin-orbit length l SO and coherence length l ϕ are determined as a function of the magnetic field magnitude and direction. Studying the angular maps of the WAL signal, we demonstrate that the average SOI within the nanowire is isotropic and that our findings are consistent with a semiclassical quasi-1D model of WAL adapted to include the geometrical constraints of the nanostructure. Moreover, by acting on properly designed side gates, we apply an external electric field introducing an additional vectorial Rashba spin-orbit component whose strength can be controlled by external means. These results give important hints on the intrinsic nature of suspended nanowire and can be interesting for the field of spintronics as well as for the manipulation of Majorana bound states in devices based on hybrid semiconductors.Keywords spin-orbit interaction, nanowire, indium arsenide, weak anti-localization, Rashba effect Over the past decades there has been a growing interest in the study of the spin-orbit interactions in semiconductor systems motivated by the possibility of spintronics applications and quantum computing. 1-5 Systems with strong SOI offer an ideal platform to develop cir-arXiv:1807.04344v2 [cond-mat.mes-hall]

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Josephson Diode Effect in High-Mobility InSb Nanoflags

Turini

Salimian

Carrega

et al. 2022

Nano Lett.

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We report nonreciprocal dissipation-less transport in single ballistic InSb nanoflag Josephson junctions. Applying an inplane magnetic field, we observe an inequality in supercurrent for the two opposite current propagation directions. Thus, these devices can work as Josephson diodes, with dissipation-less current flowing in only one direction. For small fields, the supercurrent asymmetry increases linearly with external field, and then it saturates as the Zeeman energy becomes relevant, before it finally decreases to zero at higher fields. The effect is maximum when the in-plane field is perpendicular to the current vector, which identifies Rashba spin− orbit coupling as the main symmetry-breaking mechanism. While a variation in carrier concentration in these high-quality InSb nanoflags does not significantly influence the supercurrent asymmetry, it is instead strongly suppressed by an increase in temperature. Our experimental findings are consistent with a model for ballistic short junctions and show that the diode effect is intrinsic to this material.

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Photonic Heat Rectification in a System of Coupled Qubits

et al. 2021

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Evidence of Josephson Coupling in a Few-Layer Black Phosphorus Planar Josephson Junction

et al. 2022

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Setting up strong Josephson coupling in van der Waals materials in close proximity to superconductors offers several opportunities both to inspect fundamental physics and to develop cryogenic quantum technologies. Here we show evidence of Josephson coupling in a planar few-layer black phosphorus junction. The planar geometry allows us to probe the junction behavior by means of external gates, at different carrier concentrations. Clear signatures of Josephson coupling are demonstrated by measuring supercurrent flow through the junction at milli-Kelvin temperatures. Manifestation of a Fraunhofer pattern with a transverse magnetic field is also reported, confirming the Josephson coupling. These findings represent evidence of proximity Josephson coupling in a planar junction based on a van der Waals material beyond graphene and will expedite further studies, exploiting the peculiar properties of exfoliated black phosphorus thin flakes.

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Andrea Iorio

A Josephson phase battery

Vectorial Control of the Spin–Orbit Interaction in Suspended InAs Nanowires

Josephson Diode Effect in High-Mobility InSb Nanoflags

Photonic Heat Rectification in a System of Coupled Qubits

Evidence of Josephson Coupling in a Few-Layer Black Phosphorus Planar Josephson Junction

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