Development of Theory and Experiment in the Field Of Sensor-Actuator Quantum Technologies of Biomimetic Materials

УДК 538.9:539.21

  • Mark S. Zhukovsky Polzunov Altai State Technical University, Barnaul, Russia Email: mark@zhukosvky.org
DOI_disc_logo https://doi.org/10.14258/izvasu(2024)1-02
Keywords: quantum sensor-actuator technologies, quantum nanoelectromechanical systems, biomimetic materials, quantum physical chemistry, theory, experiment, computer modeling

Abstract

The review analyzes the problem of a unified approach to experimental and theoretical descriptions of parallel relationships in attosecond reactions of subatomic quasiparticles and femtosecond transformations at the atomic scale in biomimetic materials. Solutions to the problem appeared on the brink of the 2020s, when synchrotron-generated attosecond single-period photons enabled studying their influence on subatomic quantum dynamics. They paved the way for quantum technologies to control attosecond dynamics of electron pairs and electrons entangled with single-period photons. The considered solutions of the three main problems provide real prospects for development of quantum nanoelectromechanical sensor-actuator self-assembly and self-organization technologies for biomimetic materials, starting from the attosecond-subatomic scale and ending with femtosecond atomic processes. The significance and relevance of building quantum physical chemistry models and performing computer predictions of hierarchical control system mechanisms for quantum technologies are discussed and considered at the subatomic, atomic, and at higher nano-, micro-, and mesoscale structure levels of biomimetic materials.

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Author Biography

Mark S. Zhukovsky, Polzunov Altai State Technical University, Barnaul, Russia

Candidate of Sciences in Chemistry, Associate Professor of the Department of Information Systems in Economics

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Published
2024-04-05
How to Cite
Zhukovsky M. S. Development of Theory and Experiment in the Field Of Sensor-Actuator Quantum Technologies of Biomimetic Materials // Izvestiya of Altai State University, 2024, № 1(135). P. 19-29 DOI: 10.14258/izvasu(2024)1-02. URL: http://izvestiya.asu.ru/article/view/%282024%291-02.
Issue
No 1(135) (2024): Известия Алтайского государственного университета
Section
Физика

Copyright (c) 2024 Марк Сергеевич Жуковский

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