☆ 4.5 Article

Influence of errors on the transport of quantum information through distant quantum dot spin qubits

PHYSICS LETTERS A (2022)

相关参考文献

注意：仅列出部分参考文献，下载原文获取全部文献信息。

Article Materials Science, Multidisciplinary

Dissipation and gate timing errors in SWAP operations of qubits

Nathan L. Foulk et al.

Summary: The research finds that randomness in dissipation parameter has little effect on the fidelity of SWAP gates in currently fabricated Si circuits, while gate timing error leads to an optimal value of the exchange coupling strength for SWAP gates, beyond which fidelity begins to decrease.

PHYSICAL REVIEW B (2022)

添加到收藏夹

Article Optics

Pulse engineering of a global field for robust and universal quantum computation

Ingvild Hansen et al.

Summary: The paper introduces the SMART qubit protocol, which encodes qubits less sensitive to parameter variability in a global field, improving qubit coherence times, particularly in large-scale systems. Spins in silicon quantum dots achieve one- and two-qubit control electrically, offering hope for scalability in spin-based quantum computer architectures.

PHYSICAL REVIEW A (2021)

添加到收藏夹

Article Materials Science, Multidisciplinary

Protecting quantum information in quantum dot spin chains by driving exchange interactions periodically

John S. Van Dyke et al.

Summary: Recent work has shown that periodically driving exchange interactions in quantum dot systems can enhance the protection and manipulation of multispin states, significantly increasing the coherence times of entangled states. This technique can benefit quantum information applications in various quantum dot systems, such as GaAs and Si. Additionally, constructing time-crystal-inspired gates between singlet-triplet qubits with high fidelity can further improve the performance of quantum dot spin systems.

PHYSICAL REVIEW B (2021)

添加到收藏夹

Review Chemistry, Multidisciplinary

Quantum Algorithms for Quantum Chemistry and Quantum Materials Science

Bela Bauer et al.

CHEMICAL REVIEWS (2020)

添加到收藏夹

Article Materials Science, Multidisciplinary

Spin shuttling in a silicon double quantum dot

Florian Ginzel et al.

PHYSICAL REVIEW B (2020)

添加到收藏夹

Article Quantum Science & Technology

Coherent transfer of quantum information in a silicon double quantum dot using resonant SWAP gates

A. J. Sigillito et al.

NPJ QUANTUM INFORMATION (2019)

添加到收藏夹

Article Materials Science, Multidisciplinary

Optimal control of universal quantum gates in a double quantum dot

Leonardo K. Castelano et al.

PHYSICAL REVIEW B (2018)

添加到收藏夹

Article Multidisciplinary Sciences

Quantum spin transistor with a Heisenberg spin chain

O. V. Marchukov et al.

NATURE COMMUNICATIONS (2016)

添加到收藏夹

Review Quantum Science & Technology

Quantum algorithms: an overview

Ashley Montanaro

NPJ QUANTUM INFORMATION (2016)

添加到收藏夹

Article Physics, Multidisciplinary

Quantum error correction for quantum memories

Barbara M. Terhal

REVIEWS OF MODERN PHYSICS (2015)

添加到收藏夹

Article Optics

Large-scale modular quantum-computer architecture with atomic memory and photonic interconnects

C. Monroe et al.

PHYSICAL REVIEW A (2014)

添加到收藏夹

Article Multidisciplinary Sciences

Scalable architecture for a room temperature solid-state quantum information processor

N. Y. Yao et al.

NATURE COMMUNICATIONS (2012)

添加到收藏夹

Article Physics, Multidisciplinary

Entanglement distribution for a practical quantum-dot-based quantum processor architecture

Timothy P. Spiller et al.

NEW JOURNAL OF PHYSICS (2007)

添加到收藏夹

Article Chemistry, Physical

Vibrational molecular quantum computing: Basis set independence and theoretical realization of the Deutsch-Jozsa algorithm

CM Tesch et al.

JOURNAL OF CHEMICAL PHYSICS (2004)

添加到收藏夹

Article Optics

Optimal control theory for unitary transformations

JP Palao et al.

PHYSICAL REVIEW A (2003)

添加到收藏夹

Article Quantum Science & Technology

Nonlocal Properties of Two-Qubit Gates and Mixed States, and the Optimization of Quantum Computations

Yuriy Makhlin

QUANTUM INFORMATION PROCESSING (2002)

添加到收藏夹

© Peeref 2019-2024. All rights reserved.