Related papers: Large spin shuttling oscillations enabling high-fidelity single qubit gates

Large spin shuttling oscillations enabling high-fidelity single qubit gates

URL: http://arxiv.org/abs/2403.00601v1
Date: Fri, 1 Mar 2024 15:27:57 GMT
Title: Large spin shuttling oscillations enabling high-fidelity single qubit gates
Authors: Akshay Menon Pazhedath, Alessandro David, Max Oberl\"ander, Matthias M. M\"uller, Tommaso Calarco, Hendrik Bluhm and Felix Motzoi
Abstract summary: We demonstrate the possibility of significantly outperforming static EDSR-type single-qubit pulsing by taking advantage of the larger spatial mobility to achieve larger Rabi frequencies. Our theoretical results indicate that fidelities are ultimately bottlenecked by spin-valley physics, which can be suppressed through the use of quantum optimal control.
Score: 36.136619420474766
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Semiconductor quantum dots have shown impressive breakthroughs in the last years, with single and two qubit gate fidelities matching other leading platforms and scalability still remaining a relative strength. However, due to qubit wiring considerations, mobile electron architectures have been proposed to facilitate upward scaling. In this work, we examine and demonstrate the possibility of significantly outperforming static EDSR-type single-qubit pulsing by taking advantage of the larger spatial mobility to achieve larger Rabi frequencies and reduce the effect of charge noise. Our theoretical results indicate that fidelities are ultimately bottlenecked by spin-valley physics, which can be suppressed through the use of quantum optimal control, and we demonstrate that, across different potential regimes and competing physical models, shuttling based single-qubit gates retain significant advantage over existing alternatives.

Related papers

High-fidelity spin qubit shuttling via large spin-orbit interaction [0.0]
We show that the large inhomogeneity of the Zeeman field stabilizes the coherence of a moving spin state. Our findings are generally applicable to a wide range of setups and could pave the way toward large-scale quantum processors.
arXiv Detail & Related papers (2023-11-27T16:13:16Z)
Robust gates with spin-locked superconducting qubits [4.559652576355808]
We present a theoretical proposal that incorporates a continuous version of dynamical decoupling, namely spin locking, with a coupler-based CZ gate for transmons.
arXiv Detail & Related papers (2023-06-15T14:09:51Z)
Autonomous coherence protection of a two-level system in a fluctuating environment [68.8204255655161]
We re-examine a scheme originally intended to remove the effects of static Doppler broadening from an ensemble of non-interacting two-level systems (qubits) We demonstrate that this scheme is far more powerful and can also protect a single (or even an ensemble) qubit's energy levels from noise which depends on both time and space.
arXiv Detail & Related papers (2023-02-08T01:44:30Z)
Nonadiabatic quantum control of quantum dot arrays with fixed exchange using Cartan decomposition [0.0]
In semiconductor spin qubits, shuttling of spin is a practical way to generate quantum operations between distant qubits. We extend our previous results for double- and triple-dot systems, and describe a method for implementing spin shuttling in long chains of quantum dots in a nonadiabatic manner.
arXiv Detail & Related papers (2022-07-06T01:04:39Z)
Robust Nonadiabatic Holonomic Quantum Gates on Decoherence-Protected Qubits [4.18804572788063]
We propose a scheme for quantum manipulation by combining the geometric phase approach with the dynamical correction technique. Our scheme is implemented on the superconducting circuits, which also simplifies previous implementations.
arXiv Detail & Related papers (2021-10-06T14:39:52Z)
Fast high-fidelity single-qubit gates for flip-flop qubits in silicon [68.8204255655161]
flip-flop qubit is encoded in the states with antiparallel donor-bound electron and donor nuclear spins in silicon. We study the multilevel system that is formed by the interacting electron and nuclear spins. We propose an optimal control scheme that produces fast and robust single-qubit gates in the presence of low-frequency noise.
arXiv Detail & Related papers (2021-01-27T18:37:30Z)
Charge noise suppression in capacitively coupled singlet-triplet spin qubits under magnetic field [6.211541620389987]
We show that a range of nearly sweet spots appear in the coupled singlet-triplet qubit system when a strong enough magnetic field is applied externally. We further demonstrate that ramping to and from the judiciously chosen nearly sweet spot using sequences based on the shortcut to adiabaticity offers maximal gate fidelities under charge noise and phonon-induced decoherence.
arXiv Detail & Related papers (2020-11-18T16:36:50Z)
Probing the coherence of solid-state qubits at avoided crossings [51.805457601192614]
We study the quantum dynamics of paramagnetic defects interacting with a nuclear spin bath at avoided crossings. The proposed theoretical approach paves the way to designing the coherence properties of spin qubits from first principles.
arXiv Detail & Related papers (2020-10-21T15:37:59Z)
Universal non-adiabatic control of small-gap superconducting qubits [47.187609203210705]
We introduce a superconducting composite qubit formed from two capacitively coupled transmon qubits. We control this low-frequency CQB using solely baseband pulses, non-adiabatic transitions, and coherent Landau-Zener interference. This work demonstrates that universal non-adiabatic control of low-frequency qubits is feasible using solely baseband pulses.
arXiv Detail & Related papers (2020-03-29T22:48:34Z)
Entanglement generation via power-of-SWAP operations between dynamic electron-spin qubits [62.997667081978825]
Surface acoustic waves (SAWs) can create moving quantum dots in piezoelectric materials. We show how electron-spin qubits located on dynamic quantum dots can be entangled.
arXiv Detail & Related papers (2020-01-15T19:00:01Z)

This list is automatically generated from the titles and abstracts of the papers in this site.