Your search keyword '"Menno Veldhorst"' showing total 2 results

1. Enhancement of proximity-induced superconductivity in a planar Ge hole gas

Author

Kushagra Aggarwal, Andrea Hofmann, Daniel Jirovec, Ivan Prieto, Amir Sammak, Marc Botifoll, Sara Martí-Sánchez, Menno Veldhorst, Jordi Arbiol, Giordano Scappucci, Jeroen Danon, and Georgios Katsaros

Subjects

Physics, QC1-999

Abstract

Hole gases in planar germanium can have high mobilities in combination with strong spin-orbit interaction and electrically tunable g factors, and are therefore emerging as a promising platform for creating hybrid superconductor-semiconductor devices. A key challenge towards hybrid Ge-based quantum technologies is the design of high-quality interfaces and superconducting contacts that are robust against magnetic fields. In this work, by combining the assets of aluminum, which provides good contact to the Ge, and niobium, which has a significant superconducting gap, we demonstrate highly transparent low-disordered JoFETs with relatively large I_{C}R_{N} products that are capable of withstanding high magnetic fields. We furthermore demonstrate the ability of phase-biasing individual JoFETs, opening up an avenue to explore topological superconductivity in planar Ge. The persistence of superconductivity in the reported hybrid devices beyond 1.8 T paves the way towards integrating spin qubits and proximity-induced superconductivity on the same chip.

Published

2021

2. Impact of Classical Control Electronics on Qubit Fidelity

Author

J.P.G. van Dijk, Edoardo Charbon, Lieven M. K. Vandersypen, Raymond N. Schouten, Fabio Sebastiano, E. Kawakami, Menno Veldhorst, and Masoud Babaie

Subjects

Computer science, media_common.quotation_subject, design, FOS: Physical sciences, General Physics and Astronomy, Fidelity, 02 engineering and technology, spin, 01 natural sciences, Bottleneck, coupled electron, Computer Science::Emerging Technologies, 0103 physical sciences, quantum-dot, cmos, Electronic engineering, Hardware_ARITHMETICANDLOGICSTRUCTURES, 010306 general physics, Scaling, Quantum, Quantum computer, media_common, Quantum Physics, silicon, gate fidelity, dynamics, 021001 nanoscience & nanotechnology, Control electronics, Qubit, Quantum Physics (quant-ph), 0210 nano-technology, Coherence (physics)

Abstract

Quantum processors rely on classical electronic controllers to manipulate and read out the quantum state. As the performance of the quantum processor improves, non-idealities in the classical controller can become the performance bottleneck for the whole quantum computer. To prevent such limitation, this paper presents a systematic study of the impact of the classical electrical signals on the qubit fidelity. All operations, i.e. single-qubit rotations, two-qubit gates and read-out, are considered, in the presence of errors in the control electronics, such as static, dynamic, systematic and random errors. Although the presented study could be extended to any qubit technology, it currently focuses on single-electron spin qubits, because of several advantages, such as purely electrical control and long coherence times, and for their potential for large-scale integration. As a result of this study, detailed electrical specifications for the classical control electronics for a given qubit fidelity can be derived, as demonstrated with specific case studies. We also discuss the effect on qubit fidelity of the performance of the general-purpose room-temperature equipment that is typically employed to control the few qubits available today. Ultimately, we show that tailor-made electronic controllers can achieve significantly lower power, cost and size, as required to support the scaling up of quantum computers.

Published

2019