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RAS Nano & ITRussian Microelectronics

  • ISSN (Print) 0544-1269
  • ISSN (Online)3034-5480

CNOT Quantum Gate Based on Spatial Photonic Qubits Under Resonant Electro-Optical Control

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PII
S0544126924040022-1
DOI
10.31857/S0544126924040022
Publication type
Article
Status
Published
Authors
A. V. Tsukanov
  • Affiliation: Valiev Institute of Physics and Technology of the Russian Academy of Sciences
I. Yu. Kateev
  • Affiliation: Valiev Institute of Physics and Technology of the Russian Academy of Sciences
Volume/ Edition
Volume 53 / Issue number 4
Pages
297-310
Abstract
A theoretical model of a quantum node that implements the two-qubit CNOT operation with use of photonic qubits with spatial encoding is considered. Each qubit is represented by a pair of modes supporting an arbitrary superposition of single-photon states. The active element of the node is a single or double quantum dot with a tunable frequency, which coherently exchanges an energy quantum with the modes. The spectral characteristics of the quantum node elements are simulated. The probability of implementation of a controlled inversion of the qubit state is calculated depending on the system parameters.
Keywords
квантовая точка зарядовый кубит вентиль CNOT эффект Ферстера волновод микрорезонатор
Date of publication
28.07.2025
Number of purchasers
0
Views
153

References

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