Inscrição na biblioteca: Guest
Nanoscience and Technology: An International Journal

Publicou 4 edições por ano

ISSN Imprimir: 2572-4258

ISSN On-line: 2572-4266

The Impact Factor measures the average number of citations received in a particular year by papers published in the journal during the two preceding years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) IF: 1.3 To calculate the five year Impact Factor, citations are counted in 2017 to the previous five years and divided by the source items published in the previous five years. 2017 Journal Citation Reports (Clarivate Analytics, 2018) 5-Year IF: 1.7 The Immediacy Index is the average number of times an article is cited in the year it is published. The journal Immediacy Index indicates how quickly articles in a journal are cited. Immediacy Index: 0.7 The Eigenfactor score, developed by Jevin West and Carl Bergstrom at the University of Washington, is a rating of the total importance of a scientific journal. Journals are rated according to the number of incoming citations, with citations from highly ranked journals weighted to make a larger contribution to the eigenfactor than those from poorly ranked journals. Eigenfactor: 0.00023 The Journal Citation Indicator (JCI) is a single measurement of the field-normalized citation impact of journals in the Web of Science Core Collection across disciplines. The key words here are that the metric is normalized and cross-disciplinary. JCI: 0.11 SJR: 0.244 SNIP: 0.521 CiteScore™:: 3.6 H-Index: 14

Indexed in

SORET EFFECTS OF UPPER CONVECTED MAXWELL MAGNETIZED NANOFLUIDS WITH CHEMICAL REACTION

Volume 13, Edição 1, 2022, pp. 11-23
DOI: 10.1615/NanoSciTechnolIntJ.2021038892
Get accessGet access

RESUMO

In the present investigation, the author developed mathematical model of Upper Convected Maxwell (UCM) magnetized nanofluids considering the effect of Soret number and chemical reaction. Governing equations are converted to non-linear ordinary differential equations (ODE) using similarity transformation. Fifth-order Runge-Kutta-Fehlberg scheme with shooting technique is used to solve ODE. Influences of all physical parameter are described graphically and explained in details. The velocity boundary layer reduced for Maxwell parameter. Also, the concentration boundary layer declines with increasing effect of chemical reaction. To validate present code, the author considers magnetic parameter as 0.0, 0.5, 1.0, 1.5, 2.0 to compare skin-friction coefficient with previous published work.

Referências
  1. Abbas, Z., Sajjid, M., and Hayat, T., MHD Boundary Layer Flow of an Upper-Convected Maxwell Fluid in a Porous Channel, Theor. Comput. FluidDyn., vol. 20, pp. 229-238, 2006.

  2. Ahmad, Z. and Bhargav, A., Effect of Aggregation Morphology on Thermal Conductivity and Viscosity of Al2O3-CO2 Nanofluid: A Molecular Dynamics Approach, Nano Sci. Technol. Int. J., vol. 12, no. 1, pp. 19-37, 2021.

  3. Andersson, H.I., Hansen, O.R., and Holmedal, B., Diffusion of a Chemically Reactive Species from a Stretching Sheet, Int. J. Heat Mass Transf., vol. 37, pp. 659-664, 1994.

  4. Daniel, YS., Aziz, Z.A., Ismail, Z., and Salah, F., Thermal Radiation on Unsteady Electrical MHD Flow ofNanofluid over Stretching Sheet with Chemical Reaction, J. King Saudi Univ.-Sci., vol. 31, pp. 804-812, 2019.

  5. De, P., Soret-Dufour Effects on Unsteady Flow of Convective Eyring-Powell Magneto Nanofluids over a Semi Infinite Vertical Plate, BioNanoSci. vol. 9, no. 1, pp. 7-12, 2019.

  6. De, P., Mondal, H., and Bera, U.K., Heat and Mass Transfer in a Hydromagnetic Nanofluid past a Non Linear Stretching Surface with Thermal Radiation, J. Nanofluids, vol. 4, no. 2, pp. 230-238, 2015.

  7. De, P., Mondal, H., and Bera, U.K., Influence of Nanofluids on Magnetohydrodynamic Heat and Mass Transfer over a Non Isothermal Wedge with Variable Viscosity and Thermal Radiation, J. Nanofluids, vol. 3, no. 4, pp. 391-398, 2014.

  8. Hayat, T. and Abbas, Z., Channel Flow of a Maxwell Fluid with Chemical Reaction, Z. Angew. Math. Phys., vol. 59, pp.124-144, 2008.

  9. Jalal, A., Reza, R., Amin, S., Masoud, A., Somchai, W., and Minh, D.T., Effect of Magnetic Field on Laminar Forced Convective Heat Transfer of MWCNT-Fe3O4/ Water Hybrid Nanofluid in a Heated Tube, J. Therm. Anal. Calor, vol. 137, pp. 1089-1825, 2019.

  10. Jawali, C.U. and Beg, O.A., Double Diffusive Convection in a Dissipative Electrically Conducting Nanofluid Under Orthogonal Electric and Magnetic Fields: A Numerical Study, Nano. Sci. Technol. Int. J., vol. 12, no. 2, pp. 59-90, 2021.

  11. Kashyap, K.P., Ojjela, O., and Das, S.K., MHD Slip Flow of Chemically Reacting UCM Fluid through a Dilating Channel with Heat Source/Sink, Nonlinear Eng., vol. 8, pp. 523-533, 2019.

  12. Khan, L.A., Raza, M., Mir, N.A., and Ellahi, R., Effects of Different Shapes of Nanoparticles on Peristaltic Flow of MHD Nanofluids Filled in an Asymmetric Channel, J. Therm. Anal. Calor., vol. 140, pp. 879-890, 2020.

  13. Kilic, M. and Abdulvahitoglu, A., Numerical Investigation of Heat Transfer at a Rectangular Channel with Combined Effect of Nanofluids and Swirling Jets in a Vertical Radiator, Therm. Sci., vol. 23, no. 6, pp. 3627-3637, 2019.

  14. Kilic, M., A Heat Transfer Analysis from a Porous Plate with Transpiration Cooling, Therm. Sci., vol. 23, no. 5, pp. 3025-3034, 2019.

  15. Kilic, M., A Numerical Analysis of Transpiration Cooling as an Air Cooling Mechanisms, Heat Mass Transf., vol. 54, pp. 3647-3662, 2018a.

  16. Kilic, M., Numerical Investigation of Heat Transfer from a Porous Plate with Transpiration Cooling, J. Therm. Eng., vol. 4, no. 1, pp. 1632-1647, 2018b.

  17. Kilic, M. and Muhammad, A.K., Numerical Investigation of Combined Effect of Nanofluids and Multiple Impinging Jets on Heat Transfer, Therm. Sci., vol. 23, no. 5, pp. 3165-3173, 2019.

  18. Manghat, R., Sarpabhushana, M., Baby, A.K., and Basappa, S., Marangoni Convection Flow of CNTS Al2O3-Water Hybrid Nanofluids with Variable Fluid Properties, Nano. Sci. Technol. Int. J., vol. 12, no. 1, pp. 39-56, 2021.

  19. Mondal, H., De, P., Chatterjee, S., Sibanda, P., and Roy, P.K., MHD Three Dimensional Nanofluid Flow on a Vertical Stretching Surface with Heat Generation/Absorption and Thermal Radiation, J. Nanofluids, vol. 6, no. 1, pp.189-195, 2017.

  20. Mukhopadhyay, S., Golam, M.A., and Wazed, A.P.M., Effects of Transpiration on Unsteady MHD Flow of an UCM Fluid Passing through a Stretching Surface in the Presence of a First Order Chemical Reaction, Chin. Phys. B, vol. 2, p. 124701, 2013.

  21. Mythreye, A. and Balamurugan, K.S. Chemical Reaction and Soret Effects on MHD Free Convective Flow past an Infinite Vertical Porous Plate with Variable Suction, Int. J. Chem. Eng. Res., vol. 9, no. 1, pp. 51-62, 2017.

  22. Niranjan, H., Sivasankaran, S., and Bhuvaneawari, M., Chemical Reaction, Soret-Dufour Effects on MHD Mixed Convection Stagnation Point Flow with Radiation and Slip Condition, Sci. Iranica B, vol. 24, no. 2, pp. 698-706, 2017.

  23. Pal, D. and Mondal, H., Soret-Dufour Effects on Hydromagnetic Non-Darcy Convective Radiative Heat and Mass Transfer over a Stretching Sheet in Porous Medium with Viscous Dissipation and Ohmic Heating, J. Appl. FluidMech, vol. 7, no. 3, pp. 513-523, 2014.

  24. Pal, D. and Biswas, S., Influence of Chemical Reaction and Soret Effect on Mixed Convective MHD Oscil-latory Flow of Casson Fluid with Thermal Radiation and Viscous Dissipation, Int. J. Appl. Comput. Math., vol. 3, pp. 1897-1919, 2017.

  25. Palani, S., Kumar, B.R., and Kameswaran, P.K., Unsteady MHD Flow of an UCM Fluid over a Stretching Sheet with Higher Order Chemical Reaction, Ain Shams Eng. J., vol. 7, pp. 399-408, 2016.

  26. Prasad, K.V., Sujatha, A., Vijravelu, K., and Pop I., MHD Flow and Heat Transfer of a UCM Fluid over a Stretching Surface with Variable Thermophysical Properties, Meccanica, vol. 47, pp. 1425-1439, 2012.

  27. Qureshi, M.Z.A., Rubbab, Q., Irshad, S., Ahmad, S., and Aqeel, M., Heat and Mass Transfer Analysis of MHD Nanofluid Flow with Radiative Heat Effects in the Presence of Spherical Au-Metallic Nanoparticles, Nanoscale Res. Lett, vol. 11, pp. 472-482, 2016.

  28. Sajjad, A.Z., Rahmatollah, K., Habibollah, S., Habib, A., Mousa, M., and Morteza, G., Experimentally Study of the Subcooled Flow Boiling Heat Transfer of Magnetic Nanofluid in a Vertical Tube Under Magnetic Field, J. Therm. Anal. Calor., vol. 140, pp. 2805-2816, 2020.

  29. Sharma, K. and Gupta, S., Viscous Dissipation and Thermal Radiation Effects in MHD Flow of Jeffrey Nanofluid through Impermeable Surface with Heat Generation/Absorption, Nonlinear Eng., vol. 6, no. 2, pp. 153-166, 2017.

  30. Sheikholeslami, M. and Rokni, H.B., Nanofluid Two Phase Model Analysis in Existence of Induced Magnetic Field, Int. J. Heat Mass Transf., vol. 107, pp. 288-299, 2017.

  31. Swain, K., Parida, S.K., and Dash, G.C., Higher Order Chemical Reaction on MHD Nanofluid Flow with Slip Boundary Conditions: A Numerical Approach, Math. Mod. Eng. Prob., vol. 6, no. 2, pp. 293-299, 2019.

Portal Digital Begell Biblioteca digital da Begell eBooks Diários Referências e Anais Coleções de pesquisa Políticas de preços e assinaturas Begell House Contato Language English 中文 Русский Português German French Spain