About

Laboratory on Convective Heat and Mass Transfer

Tomsk State University

36 Lenin Avenue, Tomsk, 634050, Russia

 

Laboratory was created in 2014 for solution to theoretical and practical problems on convective heat and mass transfer using analytical and numerical techniques. Lab has modern computers and an opportunity to use the computing cluster SCIF Cyberia (one of leaders of supercomputer park of Russia, that is located in Tomsk State University) with modern mathematical packages (MatLab, Mathematica, CFD software ANSYS Fluent). The scientific library of Tomsk State University has an access to main databases such as ScienceDirect, SpringerLink, Scopus, Wiley, Web of Science and others.

 

Laboratory staff:

•  Dr. Mikhail Sheremet (Head of Laboratory)

•  Dr. Nadezhda Bondareva – researcher

•  Mr. Nikita Gibanov – PhD student

•  Ms. Marina Astanina – PhD student

•  Mr. Stepan Mikhailenko – PhD student

•  Ms. Darya Bondarenko – Master’s student

 

Areas of interest of our Laboratory:

•   Natural and mixed convection

•   Conjugate heat and mass transfer

•   Radiation heat transfer

•   Laminar and turbulent modes

•   Heat and mass transfer in porous media

•   Heat and mass transfer in nanofluids

•   Numerical analysis

•   Heat transfer and flow pattern in electronic systems, nuclear and chemical reactors.

•   Computational fluid dynamics

 

Projects:

Lab implemented and implements different scientific projects for Russian Science Foundation, Russian Foundation for Basic Research, Ministry of Education and Science of the Russian Federation, Grants from the President of the Russian Federation.

 

PUBLICATIONS

1. Martyushev S.G., Sheremet M.A., (2014), Conjugate natural convection combined with surface thermal radiation in an air filled cavity with internal heat source, International Journal of Thermal Sciences, 76: 51–67.

2. Martyushev S.G., Miroshnichenko I.V., Sheremet M.A., (2014), Numerical analysis of spatial unsteady regimes of conjugate convective-radiative heat transfer in a closed volume with an energy source, Journal of Engineering Physics and Thermophysics, 87: 124–134.

3. Martyushev S.G., Sheremet M.A., (2014), Conjugate natural convection combined with surface thermal radiation in a three-dimensional enclosure with a heat source, International Journal of Heat and Mass Transfer, 73: 340–353.

4. Miroshnichenko I., Sheremet M., (2015), Comparative study of standard k–ε and k–ω turbulence models by giving an analysis of turbulent natural convection in an enclosure, EPJ Web of Conferences, 82: 01057.

5. Martyushev S.G., Sheremet M.A., (2015), Numerical analysis of 3D regimes of natural convection and surface radiation in a differentially heated enclosure, Journal of Engineering Thermophysics, 24: 22–32.

6. Sheremet M.A., (2015), Unsteady conjugate natural convection in a three-dimensional porous enclosure, Numerical Heat Transfer, Part A: Applications, 68: 243–267.

7. Bondareva N.S., Sheremet M.A., (2015), Influence of uniform magnetic field on laminar regimes of natural convection in an enclosure, Thermophysics and Aeromechanics, 22: 203–216.

8. Astanina M.S., Sheremet M.A., Umavathi J.C., (2015), Unsteady natural convection with temperature-dependent viscosity in a square cavity filled with a porous medium, Transport in Porous Media, 110: 113–126.

9. Miroshnichenko I.V., Sheremet M.A., (2015), Numerical simulation of turbulent natural convection combined with surface thermal radiation in a square cavity, International Journal of Numerical Methods for Heat & Fluid Flow, 25: 1600–1618.

10. Bondareva N.S., Sheremet M.A., (2015), Study of melting of a pure gallium under influence of magnetic field in a square cavity with a local heat source, IOP Conf. Series: Materials Science and Engineering, 93: 012004-1–012004-6.

11. Miroshnichenko I.V., Sheremet M.A., (2015), Effect of buoyancy force on turbulent modes of complex heat transfer in an air-filled square cavity, IOP Conf. Series: Materials Science and Engineering, 93: 012008-1–012008-5.

12. Bondareva N.S., Sheremet M.A., Pop I., (2015), Magnetic field effect on the unsteady natural convection in a right-angle trapezoidal cavity filled with a nanofluid: Buongiorno’s mathematical model, International Journal of Numerical Methods for Heat & Fluid Flow, 25: 1924–1946.

13. Martyushev S.G., Miroshnichenko I.V., Sheremet M.A., (2015), Influence of the geometric parameter on the regimes of natural convection and thermal surface radiation in a closed parallelepiped, Journal of Engineering Physics and Thermophysics, 88: 1522–1529.

14. Sheremet M.A., Miroshnichenko I.V., (2016), Effect of surface radiation on transient natural convection in a wavy-walled cavity, Numerical Heat Transfer, Part A, 69: 369–382.

15. Bondareva N.S., Sheremet M.A., (2016), Study of melting of a pure gallium in a rectangular enclosure, Key Engineering Materials, 683: 548–554.

16. Bondareva N.S., Sheremet M.A., (2016), Numerical simulation of melting of phase change material in a square cavity with a heat source, Key Engineering Materials, 685: 104–108.

17. Miroshnichenko I.V., Sheremet M.A., (2016), Effect of thermophysical properties of solid walls on turbulent modes of complex heat transfer in an enclosure, Key Engineering Materials, 683: 540–547.

18. Miroshnichenko I.V., Sheremet M.A., (2016), Effect of surface emissivity on conjugate turbulent natural convection in an air-filled cavity with a heat source, Key Engineering Materials, 685: 315–319.

19. Gibanov N.S., Sheremet M.A., (2016), Effect of the buoyancy force on natural convection in a cubical cavity with a heat source of triangular cross-section, IOP Conf. Series: Materials Science and Engineering, 124: 012057-1–012057-4.

20. Astanina M.S., Sheremet M.A., (2016), A transient free convection study with temperature-dependent viscosity in a square cavity with a local heat source, IOP Conf. Series: Materials Science and Engineering, 124: 012039-1–012039-4.

21. Gibanov N.S., Sheremet M.A., Pop I., (2016), Free convection in a trapezoidal cavity filled with a micropolar fluid, International Journal of Heat and Mass Transfer, 99: 831–838.

22. Bondareva N.S., Sheremet M.A., Oztop H.F., Abu-Hamdeh N., (2016), Heatline visualization of MHD natural convection in an inclined wavy open porous cavity filled with a nanofluid with a local heater, International Journal of Heat and Mass Transfer, 99: 872–881.

23. Miroshnichenko I.V., Sheremet M.A., Mohamad A.A., (2016), Numerical simulation of a conjugate turbulent natural convection combined with surface thermal radiation in an enclosure with a heat source, International Journal of Thermal Sciences, 109: 172–181.

24. Sheremet M.A., Oztop H.F., Pop I., Al-Salem K., (2016), MHD free convection in a wavy open porous tall cavity filled with nanofluids under an effect of corner heater, International Journal of Heat and Mass Transfer, 103: 955–964.

25. Sheremet M.A., Revnic C., Pop I., (2017), Natural convective heat transfer through two entrapped triangular cavities filled with a nanofluid: Buongiorno's mathematical model, International Journal of Mechanical Sciences, 133: 484–494.

26. Gibanov N.S., Sheremet M.A., Oztop H.F., Al-Salem K., (2017), Effect of uniform inclined magnetic field on natural convection and entropy generation in an open cavity having a horizontal porous layer saturated with a ferrofluid, Numerical Heat Transfer A, 72: 479–494.

27. Gibanov N.S., Sheremet M.A., Ismael M.A., Chamkha A.J., (2017), Mixed convection in a ventilated cavity filled with a triangular porous layer, Transport in Porous Media, 120: 1–21. Zargartalebi H., Ghalambaz M., Sheremet M.A., Pop I., (2017), Unsteady free convection in a square porous cavity saturated with nanofluid: The case of local thermal nonequilibrium and Buongiorno’s mathematical models, Journal of Porous Media, 20: 999–1016.

28. Oztop H.F., Bondareva N.S., Sheremet M.A., Abu-Hamdeh N., (2017), Unsteady natural convection with entropy generation in partially open triangular cavities with a local heat source, International Journal of Numerical Methods for Heat & Fluid Flow, 27: 2696–2716.

29. Bondareva N.S., Sheremet M.A., (2017), Flow and heat transfer evolution of PCM due to natural convection melting in a square cavity with a local heater, International Journal of Mechanical Sciences, 134: 610–619.

30. Astanina M.S., Sheremet M.A., Oztop H.F., Abu-Hamdeh N., (2017), Natural convection in a differentially heated enclosure having two adherent porous blocks saturated with a nanofluid, European Physical Journal Plus, 132: 509.

31. Mikhailenko S.A., Sheremet M.A., (2017), Convective heat transfer combined with surface radiation in a rotating square cavity with a local heater, Numerical Heat Transfer A, 72: 697–707.

32. Miroshnichenko I.V., Sheremet M.A., (2018), Turbulent natural convection heat transfer in rectangular enclosures using experimental and numerical approaches: A review, Renewable and Sustainable Energy Reviews, 82: 40–59.

33. Astanina M.S., Riahi M.K., Abu-Nada E., Sheremet M.A., (2018), Magnetohydrodynamic in partially heated square cavity with variable properties: Discrepancy in experimental and theoretical conductivity correlations, International Journal of Heat and Mass Transfer, 116: 532–548.

34. Sheremet M.A., Pop I., Mahian O., (2018), Natural convection in an inclined cavity with time-periodic temperature boundary conditions using nanofluids: Application in solar collectors, International Journal of Heat and Mass Transfer, 116: 751–761.

35. Miroshnichenko I.V., Sheremet M.A., (2018), Turbulent natural convection combined with thermal surface radiation inside an inclined cavity having local heater, International Journal of Thermal Sciences, 124: 122–130.

36. Bondareva N.S., Sheremet M.A., Oztop H.F., Abu-Hamdeh N., (2018), Free convection in an open triangular cavity filled with a nanofluid under the effects of Brownian diffusion, thermophoresis and local heater, ASME Journal of Heat Transfer, 140: 042502.

37. Astanina M.S., Sheremet M.A., Oztop H.F., Abu-Hamdeh N., (2018), Mixed convection of Al2O3-water nanofluid in a lid-driven cavity having two porous layers, International Journal of Heat and Mass Transfer, 118: 527–537.

38. Miroshnichenko I.V., Sheremet M.A., (2018), Radiation effect on conjugate turbulent natural convection in a cavity with a discrete heater, Applied Mathematics and Computation, 321: 358–371.

39. Kozhevnikov D.A., Sheremet M.A., (2018), Natural convection with evaporation in a vertical cylindrical cavity under the effect of temperature-dependent surface tension, Continuum Mechanics and Thermodynamics, 30: 83–94.

40. Izadi M., Mohebbi R., Karimi D., Sheremet M.A., (2018), Numerical Simulation of Natural Convection Heat Transfer inside a ┴ Shaped Cavity Filled by a MWCNT-Fe3O4/Water Hybrid Nanofluids using LBM, Chemical Engineering and Processing: Process Intensification, 125: 56–66.

41. Mikhailenko S.A., Sheremet M.A., Mohamad A.A., (2018), Convective-radiative heat transfer in a rotating square cavity with a local heat-generating source, International Journal of Mechanical Sciences, 142–143: 530–540.