Nanofluid bioconvection in porous media: Oxytactic microorganisms

Journal of Porous Media

Volumn 15, Issue 3, 2012, Pages 233-248

  Kuznetsov, A V ^a  

^a North Carolina State University   (United States)

Author keywords

Brownian motion; Horizontal layer; Nanofluid bioconvection; Nanofluid saturated porous layer; Natural convection; Oxytactic microorganisms; Thermophoresis

Indexed keywords

BIOCONVECTION; DENSITY STRATIFICATION; FINITE DEPTH; HORIZONTAL LAYERS; NANO-FLUID; OSCILLATORY INSTABILITY; OXYTACTIC MICROORGANISMS; POROUS LAYERS; VERTICAL TEMPERATURE; VERTICAL TEMPERATURE GRADIENTS;

BROWNIAN MOVEMENT; MICROORGANISMS; NANOPARTICLES; NATURAL CONVECTION; POROUS MATERIALS; STABILITY; THERMOPHORESIS;

NANOFLUIDICS;

EID: 84860493997     PISSN: 1091028X     EISSN: None     Source Type: Journal    
DOI: 10.1615/JPorMedia.v15.i3.30     Document Type: Article

References (58)

1. Bang, I. C. and Kim, J. H., Thermal-fluid characterization of ZnO and SiC nanofluids for advanced nuclear power plants, NucI. Technol., vol. 170, pp. 16-27, 2010.
2. Bang, I. C., Heo, G., Jeong, Y. H., and Heo, S., An axiomatic design approach of nanofluid-engmeered nuclear safety features for generation III plus reactors, Nuct Eng. Technol., vol. 4l,pp. 1157-1170, 2009.
3. Bergman, T. L., Analysis of heat transfer enhancement in minichannel heat sinks with turbulent flow using H20 A1203 nanofluids, J. Electron. Packag., vol. 131, pp. 02 1008-1-021088-5, 2009.
4. Bharde, A., Kulkarni, A., Rao, M., Prabhune, A., and Sastry, M., Bacterial enzyme mediated biosynthesis of gold nanopartides, J. Nanosci. Nanotechnol., vol. 7, pp. 4369-4377, 2007.
5. Bhattacharya, P., Samanta, A. N., and Chakraborty, S., Numerical study of conjugate heat transfer in rectangular microchannd heat sink with A1203 H20 nanofluid, Heat Muss Thinsfer, vol. 45, pp. 1323-1333, 2009.
6. Buongiorno, J., Convective transport in nanofluids, J. Heat Transfer, vol. 128, pp. 240-250, 2006.
7. Buongiorno, J., Hu, L., Kim, S. J., Hannink, R., Truong, B., and Forrest, E., Nanofluids for enhanced economics and safety of nuclear reactors: An evaluation of the potential features, issues, and research gaps, Nuct Technol., vol. 162, pp. 80-91, 2008. (Pubitemid 351577620)
8. Chudasama, B., Vala, A. K., Andhariya, N., Mehia, R. V., and Upadhyay, R. V., Highly bacterial resistant silver nanopartides: Synthesis and antibacterial activities, J. Nanopart. Res., vol. l2,pp. 1677-1685, 2010.
9. Finlayson, B. A., The Method of WeightedResiduals and Variational Principles, New York: Academic Press, 1972.
10. Ghazvini, M. and Shokouhmand, H., Investigation of a nanofluid-cooled microchannel heat sink using fin and porous media approaches, Energy Convers. Manage., vol. 50, pp. 2373-2380, 2009.
11. Ghazvini, M., Akhavan-Behabadi, M. A., and Esmaeili, M., The effect of viscous dissipation on laminar nanofluid flow in a microchannel heat sink, Proc. Inst. Mech. Eng., Part C: I Mech. Eng. Sci., vol. 223, pp. 2697-2706, 2009.
12. He, S., Guo, Z., Zhang, Y., Zhang, S., and Gu, J. W., Biosynthesis of gold nanoparticles using the bacteria Rho dopseudomonas capsulata, Mater Lett., vol. 61, pp. 3984-3987, 2007. (Pubitemid 46936028)
13. Hill, N. A. and Pedley, T. J., Bioconvection, Fluid Dyn. Res., vol. 37, pp. 1-20, 2005. (Pubitemid 40829305)
14. Hillesdon, A. J. and Pedley, T. J., Bioconvection in suspensions of oxytactic bacteria: Linear theory, J. Fluid Mech., vol. 324, pp. 223-259, 1996. (Pubitemid 126453654)
15. Hillesdon, A. I., Pedley, T. J., and Kessler, J. O., The development of concentration gradients in a suspension of chemotactic bacteria, Bull. Math. Biol., vol. 57, pp. 299-344, 1995.
16. Ho, C. J., Wei, L. C., and Li, Z. W., An experimental investigation of forced convective cooling performance of a microchannel heat sink with A1203 water nanofluid, Appl Therm. Eng., vol. 30, pp. 96-103, 2010.
17. Husseiny, M. I., El-Aziz, M. A., Badr, Y., and Mahmoud, M. A., Biosynthesis of gold nanoparticles using Pseudomonas aeruginosa, Spectrochim. Acta, Part A: Mol. Biomot Spectrosc., vol. 67, pp. 1003-1006, 2007. (Pubitemid 46809685)
18. Jam, R. K. and Stylianopoulos, T., Delivering nanomedicine to solid tumors, Nature Rev. Cliii. Oncol., vol. 7, pp. 653-664, 2010.
19. Kole, M. and Dey, T. K., Thermal conductivity and viscosity of AbC3 nanofluid based on car engine coolant, I Phyc. D: Appl Phys., vol. 43, p. 315501, 2010a.
20. Kole. M. and Dey. T. K.. Viscosity of alumina nanoparticles dispersed in car engine coolant, Exp. Therm. Fluid 3d., vol. 34, pp. 677-683, 2010b.
21. Kuznetsov, A. V., Investigation of the onset of thermobioconvection in a suspension of oxytactic microorganisms in a shallow fluid layer heated from below, Theoret. Comput. Fluid Dyn., vol. 19, pp. 287-299, 2005a. (Pubitemid 41202958)
22. Kuznetsov, A. V., Thermo-bioconvection in a suspension of oxytactic bacteria, Int. Cominun. Heat Mass Transfer, vol. 32, pp. 991-999, 2005b. (Pubitemid 40960003)
23. Kuznetsov, A. V., The onset of thermo-bioconvection in a shallow fluid saturated porous layer heated from below in a suspension of oxytactic microorganisms, Eur J. Mech. B Fluids, vol. 25, pp. 223 233, 2006. (Pubitemid 43220272)
24. Kuznetsov, A. V., Nanofluid bioconvection in a horizontal fluid- saturated porous layer, J. Porous Media, in press, 2010a.
25. Kuznetsov, A. V., The onset of nanofluid bioconvection in a suspension containing both nanoparticles and gyrotactic microorganisms, Int. Commun. Heat Mass Transfer, vol. 37, pp. 1421-1425,2010b.
26. Kuznetsov, A. V., Nanofluid bioconvection in water-based suspensions containing nanoparticles and oxytactic microorganisms: Oscillatory instability, Nanoscale Res. Left., vol. 6, no. 1, pp. 100, 2011a.
27. Kuznetsov, A. V., Non-oscillatory and oscillatory nanofluid biothermal convection in a horizontal layer of finite depth, Eur. J. Mech. B Fluids, vol. 30, no. 2, pp. 156-165, 2011b.
28. Kuznetsov, A. V., Nanofluid bioconvection: Interaction of microorganisms oxytactic upswimming, nanoparticle distribution and heating cooling from below, Theoret. Comput. Fluid Dyn., vol. 26,pp. 291-310, 2012.
29. Kuznetsnv, A. V. and Nield, D. A., Effect nf local thermal non- equilibrium nn the nnset nf cnnvection in a pnrnns medium layer satnrated by a nanofluid, Tronsp. Poroo,s Media, vol. 83, pp. 425-436, 2010a.
30. Kuznetsov, A. V. and Nield, D. A., Thermal instability in a porous medium layer saturated by a nanofluid Brinkman model, Tronsp. Poro its Media, vol. 81, pp. 409-422, 2010b.
31. Li, J. and Kleinstreuer, C., Thermal performance of nanofluid flow in microchannels, Int. J. Heal Flaid Flow, vol. 29, pp. 1221-1232,2008.
32. Lin, F. Y. H., Sabri, M., Alirezaie, J., Li, D. Q., and Sherman, P. M., Development of a nanoparticle-labeled microfluidic immunoassay for detection of pathogenic microorganisms, Clin. Diagn. Lab. Jomionol., vol. 12, pp. 418-425, 2005. (Pubitemid 41175337)
33. Lv, J., Zhou, L., Bai, M., Liu, J. W., and Xu, Z., Numerical simulation of the improvement to the heat transfer within the internal combustion engine by the application of nanofluids, J. Enhanced Heal Transfer, vol. 17, pp. 93-109, 2010.
34. Mahjoob, S. and Vafai, K., A synthesis of fluid and thermal transport models for metal foam heat exchangers. Int.J. Heal Macs Transfer, vol. 51, pp. 3701-3711, 2008.
35. Mandal, D., Bolander, M. F., Mukhopadhyay, D., Sarkar, G., and Mukherjee, P., The use of microorganisms for the formation of metal nanoparticles and their application, Appl Microhiol. Biolechnol., vol. 69, pp. 485-492, 2006. (Pubitemid 41830856)
36. Maynard, R., Physical properties of hyper-porous systems, PhysicaA,vol. 168, pp. 469-477, 1990.
37. Metcalfe, A. M. and Pedley, T. J., Bacterial bioconvection: Weakly nonlinear theory for pattern selection, J. Floid Mech., vol. 370, pp. 249-270, 1998. (Pubitemid 128490030)
38. Metcalfe, A. M. and Pedley, T. J., Falling plumes in bacterial bioconvection, J. Flaid Mech., vol. 445, pp. 121-149, 2001. (Pubitemid 32984214)
39. Mohanpuria, P., Rana, N. K., and Yadav, S. K., Biosynthesis of nanoparticles: Technological concepts and future applications, J. Nanoparl. Res., vol. 10, pp. 507-517, 2008.
40. Nair, H. B., Sung, B., Yadav, V. R., Kannappan, R., Chaturvedi, M. M., and Aggarwal, B. B., Delivery of anti- inflammatory nutraceuticals by nanoparticles for the prevention and treatment of cancer, Biocheol. Pharoiacol., vol. 80, pp. 1833-1843, 2010.
41. Nguyen, C. T., Roy, G., Gauthier, C., and Galanis, N., Heat transfer enhancement using A1203 water nanofluid for an electronic liquid cooling system, Appl. Therm. Eng., vol. 27, pp. 1501-1506, 2007. (Pubitemid 46187157)
42. Nield, D. A. and Bejan, A., Conveclion in Poroos Media, 3rd ed., New York: Springer, 2006.
43. Nield, D. A. and Kuznetsov, A. V., Thermal instability in a porous medium layer saturated by a nanofluid, Int. J. Heal Mass Transfer, vol. 52, pp. 5796-5801, 2009.
44. Nield, D. A. and Kuznetsov, A. V., The effect of local thermal nonequilibrium on the onset of convection in a nanofluid, J. Heal Transfer, vol. 132, p. 052405, 2010a.
45. Nield, D. A. and Kuznetsov, A. V., The onset of convection in a horizontal nanofluid layer of finite depth, Ear I. Mech. B Flails, vol. 29, no. 3, pp. 217-223, 2010b.
46. Pedley, T. J., Instability of uniform micro-organism suspensions revisited, J. FloidMech., vol. 647, pp. 335-359, 2010.
47. 2 nanocomposites: Synthesis and harmful algae bloom UVphotoelimination, Appl Calal, B: Environ., vol. 98, pp. 229-234, 2010.
48. Rournanie, M., Delattre, C., Mittler, F., Marchand, G., Meille, V., de Bellefon, C., Pijolat, C., Tournier, G., and Pouteau, P., Enhancing surface activity in silicon microreactors: Use of black silicon and alumina as catalyst supports for chemical and biological applications, Chem. Eng. J, vol. 135, pp. S317-S326, 2008. (Pubitemid 350088605)
49. Roy, G. C., Nguyen, C. T., and Comeau, M., Numerical investigation of electronic component cooling enhancement using nanofluids in a radial flow cooling system, J. Enhanced Heal Transfer, vol. 13, pp. 101-115, 2006. (Pubitemid 44520252)
50. Sadhasivam, S., Shanmugam, P., and Yun, K., Biosynthesis of silver nanoparticles by Slreplomyces hygroscopicos and antimicrobial activity against medically important pathogenic microorganisms, Colloids Sorf B: Bioinlerfaces, vol. 81, pp. 358-362, 2010.
51. Sastry, M., Ahmad, A., Khan, M. I., and Kumar, R., Biosynthesis of metal nanoparticles using fungi and actinomycete, Corr Sci., vol. 85, pp. 162-170, 2003. (Pubitemid 39160563)
52. Shafahi, M., Bianco, V., Vafai, K., and Manca, O., An investigation of the thermal performance of cylindrical heat pipes using nanofluids, Int. J. Heal Mass Transfer, vol. 53, pp. 376-383, 2010a.
53. Shafahi, M., Bianco, V., Vafai, K., and Manca, O., Thermal performance of flat-shaped heat pipes using nanofluids, Int. J. Heal Mass Transfer, vol. 53, pp. 1438-1445, 2010b.
54. Sokolov, A., Goldstein, R. E., Feldchtein, F. I., and Aranson, I. S., Enhanced mixing and spatial instability in concentrated bacterial suspensions, Phys. Rev E, vol. 80, p. 031903, 2009.
55. Tsai, T., Liou, D., Kuo, L., and Chen, P., Rapid mixing between ferro-nanofluid and water in a semi-active Y-type micromixer, Sens. Acloalors, A, vol. 153, pp. 267 273, 2009.
56. Vasu, V., Krishna, K. R., and Kumar, A. C. S., Heat transfer with nanofluids for electronic cooling, Int. J. Malec Prod. Technol., vol. 34, pp. 158-171, 2009.
57. Winer, I., Wang, S., Lee, Y. K., Fan, W., Gong, Y., BurgosOjeda, D., Spahlinger, G., Kopelman, R., and Buck- anovich, R. I., F3-Targeted cisplatin-hydrogel nanoparticles as an effective therapeutic that targets both murine and human ovarian tumor endothelial cells in vivo, Cancer Res., vol. 70, pp. 8674 8683, 2010.
58. Zhao, C. Y., Lu, T. J., and Hodson, H. P., Measurements of ther- mal radiation in ultralight metal foams with open cells, Proc. Inst Mech. Eng., Part C: Mech. Eng. 3d., vol. 218, pp. 1297-1307, 2004.