Abstract
One of the main motivations for our research was to find a connection between the Brownian motion of microorganisms within fractal nature, with the idea of developing an appropriate procedure and method to control the microorganism’s motion direction and predict the position of the microorganism in time. In this paper, we have followed the results of the very rear microorganism’s motion sub-microstructures in the experimental microstructure analysis already observed and published. All of these data have been good basis to describe the motion trajectory by time interval method and fractals. We successfully defined the diagrams in two and three-dimensions and we were able to establish the control of Brownian chaotic motion as a bridge between chaotic disorders to control disorder. This significant study opens a new possibility for future investigation and the new potential of total control of the microorganism motion. These perspectives and findings provide significant data for getting more information from these bio systems. They can also be applied, based on self-similarities and biomimetics, to particle physical systems and matter, generally.
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Acknowledgements
The author gratefully acknowledges the financial support of Ministry for Education, Science and Technological Development of Serbia, and to NSF (The National Science Foundation) North Carolina, USA, for this work.
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Mitić, V. et al. (2023). Brownian Motion Fractal Nature Frontiers Within the Matter. In: Najman, S., et al. Bioceramics, Biomimetic and Other Compatible Materials Features for Medical Applications. Engineering Materials. Springer, Cham. https://doi.org/10.1007/978-3-031-17269-4_16
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DOI: https://doi.org/10.1007/978-3-031-17269-4_16
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