Biomimetic amelioration of zirconium nanoparticles on a rigid substrate over viscous slime—a physiological approach

doi:10.1007/s10483-023-3030-7

摘要/Abstract

摘要： In this article, an investigation is conducted to study the precise role of zirconium nanoparticles that exist in a slime-like fluid subject to specific adjustments. Since gliding is a technique of mobility used by bacteria that lack motility components, bacteria travel on their own strength in gliding locomotion by secreting a layer of slime on the substrate. A model of an undulating sheet over a layer of slime of a Rabinowitsch fluid is investigated as a potential model of bacteria's gliding motility. With the aid of long wavelength approximation, the equations governing the circulation of slime underneath the cells are established and analytically solved. The effects of pseudoplasticity, dilatation and non-Newtonian parameter on the behavior of zirconium concentration, speed of microorganism (bacteria), streamline patterns, and pressure rise for non-Newtonian and Newtonian fluids are compared. The power required for propulsion is also investigated. Physical interpretation for the pertinent variables has been graphically discussed against the parameters under consideration. It is found that with the increase in the concentration of zirconium nanoparticles, the bacterial flow is accelerated and attains its maximum near the rigid substrate wall while an opposite behavior is noticed in the rest region.

关键词: zirconium nanoparticle, gliding bacterium, Grashof heat transfer, glider's speed, Rabinowitsch fluid

Abstract: In this article, an investigation is conducted to study the precise role of zirconium nanoparticles that exist in a slime-like fluid subject to specific adjustments. Since gliding is a technique of mobility used by bacteria that lack motility components, bacteria travel on their own strength in gliding locomotion by secreting a layer of slime on the substrate. A model of an undulating sheet over a layer of slime of a Rabinowitsch fluid is investigated as a potential model of bacteria's gliding motility. With the aid of long wavelength approximation, the equations governing the circulation of slime underneath the cells are established and analytically solved. The effects of pseudoplasticity, dilatation and non-Newtonian parameter on the behavior of zirconium concentration, speed of microorganism (bacteria), streamline patterns, and pressure rise for non-Newtonian and Newtonian fluids are compared. The power required for propulsion is also investigated. Physical interpretation for the pertinent variables has been graphically discussed against the parameters under consideration. It is found that with the increase in the concentration of zirconium nanoparticles, the bacterial flow is accelerated and attains its maximum near the rigid substrate wall while an opposite behavior is noticed in the rest region.

Key words: zirconium nanoparticle, gliding bacterium, Grashof heat transfer, glider's speed, Rabinowitsch fluid

中图分类号:

76Bxx

S. I. ABDELSALAM, A. Z. ZAHER. Biomimetic amelioration of zirconium nanoparticles on a rigid substrate over viscous slime—a physiological approach[J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(9): 1563-1576.

参考文献

[1] MADIGAN, M. T., BENDER, K. S., BUCKLEY, D. H., SATTLEY, W. M., and STAGK, D. A. Brock Biology of Microorganisms (15th Edition), Pearson, London (2018)
[2] ASGHAR, Z., SHAH, R. A., and ALI, N. A computational approach to model gliding motion of an organism on a sticky slime layer over a solid substrate. Biomechanics and Modeling in Mechanobiology, 21, 1441-1455(2022)
[3] ASGHAR, Z., ALI, N., and SAJID, M. Interaction of gliding motion of bacteria with rheological properties of the slime. Mathematical Biosciences, 290, 31-40(2017)
[4] KYZAS, G. Z. and MITROPOULOS, A. C. Novel Nanomaterials--Synthesis and Applications, InTech, London, United Kingdom (2018)
[5] COSTERTON, J. W., MURRAY, R. G. E., and RABINO, C. F. Observations on the motility and the structure of vitreoscilla. Canadian Journal of Microbiology, 7, 329-339(1961)
[6] HALFEN, L. N. and CASTENHOLZ, R. W. Gliding in the blue-green alga: a possible mechanism. nature, 225, 1163-1165(1970)
[7] HALFEN, L. N. and CASTENHOLZ, R. W. Gliding in the blue-green alga. Journal of Phycology, 7, 133-144(1971)
[8] HUMPHREY, B. A., DICKSON, M. R., and MARSHALL, K. C. Physicochemical and in situ observations on the adhesion of gliding bacteria to surfaces. Archives of Microbiology, 120, 231-238(1979)
[9] READ, N., CONNELL, S., and ADAMS, D. G. Nanoscale visualization of a fibrillar array in the cell wall of filamentous cyanobacteria and its implications for gliding motility. Journal of Bacteriology, 189, 7361-7366(2007)
[10] HOICZYK, E. Gliding motility in cyanobacteria: observations and possible explanations. Archives of Microbiology, 174, 11-17(2000)
[11] RIDGWAY, H. F. and LEWIN, R. A. Characterization of gliding motility in flexibacter polymorphus. Cell Motility and the Cytoskeleton, 11, 46-63(1988)
[12] BURCHARD, A. C., BURCHARD, R. P., and KLOETZEL, J. A. Intracellular, periodic structures in the gliding bacterium myxococcus xanthus. Journal of Bacteriology, 132, 666-672(1977)
[13] DICKSON, M. R., KOUPRACH, S., HUMPHREY, B. A., and MARSHALL, K. C. Does gliding motility depend on undulating membranes? Micron, 11, 381-382(1980)
[14] O'BRIEN, R. W. The gliding motion of a bacterium, flexibactor strain BH 3. The Journal of the Australian Mathematical Society Series B: Applied Mathematics, 23, 2-16(1981)
[15] LAPIDUS, I. R. and BERG, H. C. Gliding motility of cytophaga sp. strain U67. Journal of Bacteriology, 151, 384-398(1982)
[16] VENKATARAJ, S., KAPPERTZ, O., WWEIS, H., DRESE, R., JAYAVEL, R., and WUTTIG, M. Structural and optical properties of thin zirconium oxide films prepared by reactive direct current magnetron sputtering. Journal of Applied Physics, 92, 3599-3607(2002)
[17] GAO, P., MENG, L. J., SANTOS, M. P., TEIXEIRA, V., and ANDRITSCHKY, M. Characterisation of ZrO₂ films prepared by rf reactive sputtering at different O₂ concentrations in the sputtering gases. Vacuum, 56, 143-148(2000)
[18] PETIT, M. and MONOT, J. Functionalization of Zirconium Oxide Surfaces, John Wiley, New Jersey, 168-199(2015)
[19] MOHANTY, U. S., AWAN, F. U., ALI, M., AFTAB, A., KESHAVARZ, A., and IGLAUER, S. Physicochemical characterization of zirconia nanoparticle-based sodium alginate polymer suspension for enhanced oil recovery. Energy and Fuels, 35, 19389-19398(2021)
[20] BARAI, R. M., KUMAR, D., WANKHADE, A. V., SAYED, A. R., and JUNANKAR, A. A. Experimental study of thermal characteristics of ZrO₂/EG nanofluid for application of heat transfer. Environmental Science and Pollution Research, 30, 25523-25531(2023)
[21] LEONETTI, B. Mesoporous Zirconia Nanoparticles for Biomedical Applications: Characterization, Functionalization and Case Studies as Antibiofouling Agents, Ph.D. dissertation, Ca' Foscari University of Venice, 851554(2017)
[22] ALZANBAQI, S. D., ALOGAIEL, R. M., ALASMARI, M. A., Al-ESSA, A. M., KHOGEER, L. N., ALANAZI, B. S., HAWSAH, E. S., SHAIKH, A. M., and IBRAHIM, M. S. Zirconia crowns for primary teeth: a systematic review and meta-analyses. International Journal of Environmental Research and Public Health, 19, 2-18(2022)
[23] BALAJI, S. and SHANMUGAM, V. K. Enhanced antibiofilm activity of endophytic bacteria bediated zirconium nanoparticles. Biointerface Research in Applied Chemistry, 12, 74-82(2021)
[24] MEHDIKHANI, H., AQABABA, H., and SADEGHI, L. Effect of zirconium oxide nanoparticle on serum level of testosterone and spermatogenesis in the rat: an experimental study. International Journal of Reproductive BioMedicine, 18, 765-776(2020)
[25] ABDELSALAM, S. I., MEKHEIMER, K. S., and ZAHER, A. Z. Dynamism of a hybrid Casson nanofluid with laser radiation and chemical reaction through sinusoidal channels. Waves in Random and Complex Media, 4, 1-22(2022)
[26] ABDELSALAM, S. I., VELASCO-HERNÁNDEZ, J. X., and ZAHER, A. Z. Electro-magnetically modulated self-propulsion of swimming sperms via cervical canal. Biomechanics and Modeling in Mechanobiology, 20, 861-878(2021)
[27] ZAHER, A. Z., MOAWAD, A. M. A., MEKHEIMER, K. S., and BHATTI, M. M. Residual time of sinusoidal metachronal ciliary flow of non-Newtonian fluid through ciliated walls: fertilization and implantation. Biomechanics and Modeling in Mechanobiology, 20, 1-22(2021)
[28] MEKHEIMER, K. S., SHAHZADI, I., NADEEM, S., MOAWAD, A. M. A., and ZAHER, A. Z. Reactivity of bifurcation angle and electroosmosis flow for hemodynamic flow through aortic bifurcation and stenotic wall with heat transfer. Physica Scripta, 96, 015216(2021)
[29] ABDELSALAM, S. I., MEKHEIMER, K. S., and ZAHER, A. Z. Alterations in blood stream by electroosmotic forces of hybrid nanofluid through diseased artery: aneurysmal/stenosed segment. Chinese Journal of Physics, 67, 314-329(2020)
[30] ZAHER, A. Z., ALI, K. K., and MEKHEIMER, K. S. Electroosmosis forces EOF driven boundary layer flow for a non-Newtonian fluid with planktonic microorganism: Darcy Forchheimer model. International Journal of Numerical Methods for Heat & Fluid Flow, 31, 2534-2559(2021)
[31] ELDABE, N. T., GABR, M. E., ZAHER, A. Z., and ZAHER, S. A. The effect of Joule heating and viscous dissipation on the boundary layer flow of a magnetohydrodynamics micropolar-nanofluid over a stretching vertical Riga plate. Heat Transfer, 50, 4788-4805(2021)
[32] ABDELSALAM, S. I., VELASCO-HERNÁNDEZ, J. X., and ZAHER, A. Z. Electromagnetically modulated self-propulsion of swimming sperms via cervical canal. Biomechanics and Modeling in Mechanobiology, 20, 861-878(2021)
[33] ABDELSALAM, S. I. and ZAHER, A. Z. Leveraging elasticity to uncover the role of Rabinowitsch suspension through a wavelike conduit: consolidated blood suspension application. Mathematics, 19, 1-25(2021)