Suspended InAs nanowire Josephson junctions assembled via dielectrophoresis

Montemurro, Domenico; Stornaiuolo, Daniela; Massarotti, Davide; Ercolani, Daniele; Sorba, L.; Beltram, Fabio; Tafuri, F.; Roddaro, Stefano

doi:10.1088/0957-4484/26/38/385302

Cited by 23 publications

(18 citation statements)

References 48 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Disorder is always an important concern in one dimension, both from the point of view of Luttinger liquids where it is renormalization-group relevant for repulsive interactions, and in the Wigner crystal where it can drive a Peierls instability. In this respect, it is encouraging to note that recent experiments have managed to realize good contacts, 10 suspended wires, 9 and ballistic transport with a mean free path of several µm in InSb nanowires. 11 We therefore expect our predictions to be observable in these state-of-the-art wires.…”

Section: Differential Conductancementioning

confidence: 89%

Helical gaps in interacting Rashba wires at low electron densities

Schmidt

Pedder

2016

Phys. Rev. B

View full text Add to dashboard Cite

Rashba spin-orbit coupling and a magnetic field perpendicular to the Rashba axis have been predicted to open a partial gap ("helical gap") in the energy spectrum of noninteracting or weakly interacting one-dimensional quantum wires. By comparing kinetic energy and Coulomb energy we show that this gap opening typically occurs at low electron densities where the Coulomb energy dominates. To address this strongly correlated limit, we investigate Rashba wires using Wigner crystal theory. We find that the helical gap exists even in the limit of strong interactions but its dependence on electron density differs significantly from the weakly interacting case. In particular, we find that the critical magnetic field for opening the gap becomes an oscillatory function of electron density. This changes strongly the expected signature of the helical gap in conductance measurements.Comment: 4 pages main text, 6 pages appendix, 6 figure

show abstract

Section: Differential Conductancementioning

confidence: 89%

Helical gaps in interacting Rashba wires at low electron densities

Schmidt

Pedder

2016

Phys. Rev. B

View full text Add to dashboard Cite

show abstract

“…5,[28][29][30][31][32][33][34] Such an asymmetry causes the pinning of the spin-orbit field in the plane of the substrate, as demonstrated for nanowire quantum dots and for Majorana nanowires. 24,29,35 Additionally, the lack of spatial inversion symmetry in the crystal structure can introduce another spin-orbit contribution, namely the Dresselhaus SOI . 25,[31][32][33][34]36 Furthermore, local internal electric fields, caused by the Fermi level pinning at the nanowire surface, can also give extra Rashba contributions.…”

mentioning

confidence: 99%

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

et al. 2018

View full text Add to dashboard Cite

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]

show abstract

“…1(a) I-V curves of a Al-BiSe (flake) (TI)-Al junction as a function of the temperature clearly indicate an overdamped regime [9], which is retrieved in Fig. 1(c) for a Al-InAs (nanowire)-Al device [14]. In these devices, the value of the critical current density c J is strongly affected by the properties of the interface [17].…”

Section: I-v Curves Of Unconventional Junctionsmentioning

confidence: 87%

“…In Fig. 1, panels (c) [14] and (d) [15], I-V characteristics refer to junctions where the barrier is a nanowire. In all these cases we present curves with and without hysteresis to encompass nominally the relevant limits in the phase dynamics.…”

Section: Introductionmentioning

confidence: 99%

What happens in Josephson junctions at high critical current densities

Massarotti¹,

Stornaiuolo²,

Lucignano³

et al. 2017

Low Temperature Physics

View full text Add to dashboard Cite

The impressive advances in material science and nanotechnology are more and more promoting the use of exotic barriers and/or superconductors, thus paving the way to new families of Josephson junctions. Semiconducting, ferromagnetic, topological insulator and graphene barriers are leading to unconventional and anomalous aspects of the Josephson coupling, which might be useful to respond to some issues on key problems of solid state physics. However, the complexity of the layout and of the competing physical processes occurring in the junctions is posing novel questions on the interpretation of their phenomenology. We classify some significant behaviors of hybrid and unconventional junctions in terms of their first imprinting, i.e. current-voltage curves, and propose a phenomenological approach to describe some features of junctions characterized by relatively high critical current densities J c . Accurate arguments on the distribution of switching currents will provide quantitative criteria to understand physical processes occurring in high-J c junctions. These notions are universal and apply to all kinds of junctions.

show abstract

Suspended InAs nanowire Josephson junctions assembled via dielectrophoresis

Cited by 23 publications

References 48 publications

Helical gaps in interacting Rashba wires at low electron densities

Helical gaps in interacting Rashba wires at low electron densities

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

What happens in Josephson junctions at high critical current densities

Contact Info

Product

Resources

About