Email this article Optimization of quantum computations: the impact of the Doppler effect on cubit coherence
- Authors: Rakhimov R.K.1
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Affiliations:
- Institute of Materials Science of the Academy of Science of Uzbekistan
- Issue: Vol 11, No 4 (2024)
- Pages: 58-76
- Section: ELEMENTS OF COMPUTING SYSTEMS
- URL: https://journal-vniispk.ru/2313-223X/article/view/282562
- DOI: https://doi.org/10.33693/2313-223X-2024-11-4-58-76
- EDN: https://elibrary.ru/GFQRFT
- ID: 282562
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Abstract
The Doppler effect, arising from the relative motion between the source and the observer, plays a significant role in quantum computations, particularly in the context of decoherence and the state of qubits. In quantum systems where information is encoded in the states of qubits, changes in the frequency of photons caused by the Doppler effect can lead to coherence violations and a decrease in computational accuracy. These changes can cause state mixing and complicate the management of quantum interactions, increasing the probability of errors. Understanding and accounting for the Doppler effect is critically important for designing robust quantum systems, as it can manifest in various types of qubits, including photonic, atomic, and ion qubits. To minimize the impact of the Doppler effect, it is necessary to develop error correction methods and utilize technologies such as polarizing filters or feedback systems. Thus, studying the Doppler effect deepens our understanding of the mechanisms of decoherence and contributes to the creation of more stable and efficient quantum computing systems.
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##article.viewOnOriginalSite##About the authors
Rustam Kh. Rakhimov
Institute of Materials Science of the Academy of Science of Uzbekistan
Author for correspondence.
Email: rustam-shsul@yandex.com
ORCID iD: 0000-0001-6964-9260
SPIN-code: 3026-2619
Dr. Sci. (Eng.); Head, Laboratory No. 1, Institute of Renewable Energy Sources
Uzbekistan, TashkentReferences
- Buijs-Ballot C.H.D. Acoustic changes in the Netherlands electric trains, non-linear measurements of the theory of Professor Doppler. Annals of Physics and Chemistry. 1845. Vol. 66. Pp. 321–351. (In German)
- Detlaff A.A., Yavorskii B.M. Course of physics. Vol. 3: Wave processes. Optics. Atomic and nuclear physics. Moscow: Vysshaya Shkola, 1979. 511 p.
- Landau L.D., Lifshitz E.M. Theoretical physics. Vol. II: Field theory. Moscow: Nauka, 1988. 512 p.
- Streltsov V.N. Ives-Stilwell experiment and relativistic length. In: Brief communications of JINR. Dubna: JINR Publishing Department, 1992.
- Champeney D.C., Isaak G.R., Khan A.M. A time dilatation experiment based on the Mössbauer effect. Proceedings of the Physical Society. 1965. Vol. 85. No. 3. Pp. 583–593. doi: 10.1088/0370-1328/85/3/317.
- Zhilin P.A. Galileo’s relativity principle and Maxwell’s equations. St. Petersburg: Polytechnic University Publishing House, 2012. 584 p.
- Genike A.A., Pobedinsky G.G. Global satellite positioning systems and their application in geodesy. Moscow: Kartgeocenter, 2004. 355 p.
- Bogushevich A.Ya. Krasnenko N.P. Doppler effect in acoustics of an inhomogeneous moving medium. Acoustic Journal. 1988. Vol. 34. No. 4. Pp. 598–602. (In Rus.)
- Ostashev V.E. The Doppler effect in a moving medium and the change in the direction of propagation of sound emitted by a moving source. Acoustic Journal. 1988. Vol. 34. No. 4. Pp. 700–705. (In Rus.)
- Bogushevich A.Ya. On the derivation of a formula for the Doppler effect in geometric acoustics of an inhomogeneous moving medium. Acoustic Journal. 1994. Vol. 40. No. 6. Pp. 899–902. (In Rus.)
- Kologrivov V.N., Tishchenkova V.V. Optical Doppler effect. Physics Education in Higher Education Institutions. 2002. Vol. 8. No. 4. Pp. 72–77. (In Rus.)
- Rakhimov R.Kh. Possible mechanism of the pulsed quantum tunneling effect in photocatalysts based on nanostructured functional ceramics. Computational Nanotechnology. 2023. Vol. 10. No. 3. Pp. 26–34. doi: 10.33693/2313-223X-2023-10-3-26-34. EDN: QZQMCA.
- Rakhimov R.Kh., Ermakov V.P. Pulse tunneling effect. Features of interaction with matter. Observer effect. Computational Nanotechnology. 2024. Vol. 11. No. 2. Pp. 115–144. doi: 10.33693/2313-223X-2024-11-2-115-144. EDN: MWBRQW.
- Rakhimov R.Kh., Ermakov V.P. New approaches to the synthesis of functional materials with specified properties under the action of concentrated radiation and pulsed tunneling effect. Computational Nanotechnology. 2024. Vol. 11. No. 1. Pp. 214–223. (In Rus.). doi: 10.33693/2313-223X-2024-11-1-214-223. EDN: EYKREQ.
- Rakhimov R.Kh. Pulsed tunneling effect: Fundamental principles and application prospects. Computational Nanotechnology. 2024. Vol. 11. No. 1. Pp. 193–213. (In Rus.). doi: 10.33693/2313-223X-2024-11-1-193-213. EDN: EWSBUT.
- Rakhimov R.Kh. Potential of ITE to overcome technical barriers of quantum computers. Computational Nanotechnology. 2024. Vol. 11. No. 3. Pp. 11–33. doi: 10.33693/2313-223X-2024-11-3-11-33. EDN: PZNUYI.
- Rakhimov R.Kh. Interrelation and interpretation of effects in quantum mechanics and classical physics. Computational Nanotechnology. 2024. Vol. 11. No. 3. Pp. 98–124. doi: 10.33693/2313-223X-2024-11-3-98-124. EDN: QEHXLV.
- Rakhimov R.Kh. Pulsed tunneling effect: new prospects for controlling superconducting devices. Computational Nanotechnology. 2024. Vol. 11. No. 3. Pp. 161–176. doi: 10.33693/2313-223X-2024-11-3-161-176. EDN: QBGGDW.
- Rakhimov R.Kh. Fractals in quantum mechanics: from theory to practical applications. Computational Nanotechnology. 2024. Vol. 11. No. 3. Pp. 125–160. doi: 10.33693/2313-223X-2024-11-3-125-160. EDN: QFISKE.
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