Your search keyword '"Csonka, Szabolcs"' showing total 5 results

1. Parallel InAs nanowires for Cooper pair splitters with Coulomb repulsion.

Author

Kürtössy, Olivér, Scherübl, Zoltán, Fülöp, Gergő, Lukács, István Endre, Kanne, Thomas, Nygård, Jesper, Makk, Péter, and Csonka, Szabolcs

Subjects

COOPER pair, ANDREEV reflection, QUANTUM dots, NANOWIRES, ELECTRON pairs, SUPERCONDUCTORS

Abstract

Hybrid nanostructures consisting of two parallel InAs nanowires connected by an epitaxially grown superconductor (SC) shell recently became available. Due to the defect-free SC-semiconductor interface and the two quasi-one-dimensional channels being close by, these platforms can be utilized to spatially separate entangled pairs of electrons by using quantum dots (QD) in the so-called Cooper pair splitting (CPS) process. The minimized distance between the QDs overcomes the limitations of single-wire-based geometries and can boost the splitting efficiency. Here we investigate CPS in such a device where strong inter-dot Coulomb repulsion is also present and studied thoroughly. We analyze theoretically the slight reduction of the CPS efficiency imposed by the Coulomb interaction and compare it to the experiments. Despite the competition between crossed Andreev reflection (CAR) and inter-wire capacitance, a significant CPS signal is observed indicating the dominance of the superconducting coupling. Our results demonstrate that the application of parallel InAs nanowires with epitaxial SC is a promising route for the realization of parafermionic states relying on enhanced CAR between the wires. [ABSTRACT FROM AUTHOR]

Published

2022

2. Double Nanowires for Hybrid Quantum Devices.

Author

Kanne, Thomas, Olsteins, Dags, Marnauza, Mikelis, Vekris, Alexandros, Estrada Saldaña, Juan Carlos, Loric̀, Sara, Schlosser, Rasmus D., Ross, Daniel, Csonka, Szabolcs, Grove‐Rasmussen, Kasper, and Nygård, Jesper

Subjects

SEMICONDUCTOR nanowires, NANOWIRES, MOLECULAR beam epitaxy, ELECTRON transport, SUPERCONDUCTORS

Abstract

Parallel 1D semiconductor channels connected by a superconducting strip constitute the core platform in several recent quantum device proposals that rely, for example, on Andreev processes or topological effects. In order to realize these proposals, the actual material systems must have high crystalline purity, and the coupling between the different elements should be controllable in terms of their interfaces and geometry. A strategy for synthesizing double InAs nanowires by the vapor‐liquid‐solid mechanism using III‐V molecular beam epitaxy is presented. A superconducting layer is deposited onto nanowires without breaking the vacuum, ensuring pristine interfaces between the superconductor and the two semiconductor nanowires. The method allows for a high yield of merged as well as separate parallel nanowires with full or half‐shell superconductor coatings. Their utility in complex quantum devices by electron transport measurements is demonstrated. [ABSTRACT FROM AUTHOR]

Published

2022

3. Comparison of gate geometries for tunable, local barriers in InAs nanowires.

Author

Dahl Nissen, Peter, Sand Jespersen, Thomas, Grove-Rasmussen, Kasper, Márton, Attila, Upadhyay, Shivendra, Hannibal Madsen, Morten, Csonka, Szabolcs, and Nygård, Jesper

Subjects

GEOMETRY, INDIUM compounds, INDIUM arsenide, ARSENIC compounds, NANOWIRES

Abstract

We report measurements and analysis of gate-induced electrostatic barriers for electron transport in InAs nanowires. Three types of local gates are analyzed; narrow gates (50-100 nm) located on top of or below the nanowire, and wide gates overlapping the interfaces between nanowire and source and drain electrodes. We find that applying negative potentials to the local gate electrodes induces tunable barriers of up to 0.25 eV and that transport through the wire can be blocked at neutral and slightly positive potentials on the nanowire-contact gates, indicating that built-in barriers can exist at the nanowire-contact interface. The contact gates can be biased to remove the unwanted interface barriers occasionally formed during processing. From the temperature dependence of the conductance, the barrier height is extracted and mapped as a function of gate voltage. Top and bottom gates are similar to each other in terms of electrostatic couplings (lever arms ∼0.1-0.2 eV/ V) and threshold voltages for barrier induction (Vg∼-1 to -2 V), but low temperature gate sweeps suggest that device stability could be affected by the differences in device processing for the two gate geometries. [ABSTRACT FROM AUTHOR]

Published

2012

4. In-situ mechanical characterization of wurtzite InAs nanowires

Author

Erdélyi, Róbert, Hannibal Madsen, Morten, Sáfrán, György, Hajnal, Zoltán, Endre Lukács, István, Fülöp, Gergő, Csonka, Szabolcs, Nygård, Jesper, and Volk, János

Subjects

*INDIUM arsenide, *WURTZITE, *NANOWIRES, *MECHANICAL behavior of materials, *CRYSTAL structure, *SCANNING electron microscopy, *CRYSTALLOGRAPHY

Abstract

Abstract: High aspect ratio vertical InAs nanowires were mechanically characterized in a scanning electron microscope equipped with two micromanipulators. One, equipped with a calibrated atomic force microscope probe, was used for in-situ static bending of single nanowires along the 〈11–20〉 crystallographic direction. The other one was equipped with a tungsten tip for dynamic resonance excitation of the same nanowires. This setup enabled a direct comparison between the two techniques. The crystal structure was analyzed using transmission electron microscopy, and for InAs nanowires with a hexagonal wutzite crystal structure, the bending modulus value was found to BM=43.5GPa. This value is significantly lower than previously reported for both cubic zinc blende InAs bulk crystals and InAs nanowires. Besides, due to their high resonance quality factor (Q>1200), the wurtzite InAs nanowires are shown to be a promising candidate for sub-femtogram mass detectors. [Copyright &y& Elsevier]

Published

2012

5. Electrical tuning of Rashba spin-orbit interaction in multigated InAs nanowires.

Author

Scherübl, Zoltán, Fülöp, Gergő, Madsen, Morten H., Nygård, Jesper, and Csonka, Szabolcs

Subjects

*SPIN-orbit interactions, *NANOWIRES

Abstract

Indium arsenide nanowires (NWs) are a promising platform to fabricate quantum electronic devices, among other advantages they have strong spin-orbit interaction (SOI). The controlled tuning of the SOI is desired in spin-based quantum devices. In this study we investigate the possibility of tuning the SOI by electrostatic fields generated by a back gate and two side gates placed on the opposite sides of the NW. The strength of the SOI is analyzed by weak anti-localization effect. We demonstrate that the strength of the SOI can be strongly tuned up to a factor of 2 with the electric field across the NW, while the average electron density is kept constant. Furthermore, a simple electrostatic model is introduced to calculate the expected change of the SOI. Good agreement is found between the experimental results and the estimated Rashba-type SOI generated by the gate-induced electric field. [ABSTRACT FROM AUTHOR]

Published

2016