Mikhail A. Sheremet
University
Tomsk State University
English level
Advanced
The direction of training for which the graduate student will be accepted
01.06.01 Mathematics and Mechanics (educational program)
1.1.9 Mechanics of fluid, gas and plasma (field of the educational program)
1.1.9 Mechanics of fluid, gas and plasma (field of the educational program)
The code of the field of study for which the graduate student will be accepted
01.02.05
01.04.14
01.04.14
List of research projects of a potential supervisor
(participation /leadership)
(participation /leadership)
1) The Tomsk State University Development Programme (Priority–2030) (leadership)
2) Government task of the Ministry of Science and Higher Education of the Russian Federation (Project Number FSWM–2020-0036) (participation)
2) Government task of the Ministry of Science and Higher Education of the Russian Federation (Project Number FSWM–2020-0036) (participation)
List of possible research topics
- Convective-radiative heat transfer in complex domains;
- Conjugate heat transfer in a window system;
- Conjugate heat transfer in solar collectors;
- Turbulent natural convection in irregular chambers with local heaters;
- Complex heat transfer in porous enclosures with local heat sources;
- Complex heat transfer in building elements;
- Melting/solidification of PCM in engineering systems
Supervisor’s research interests
- Conjugate heat and mass transfer
- Natural, mixed and forced convection
- Heat and mass transfer in porous media
- Fluid flow and heat transfer in nanofluids
- Turbulent heat and mass transfer
- Convective-radiative heat transfer
- Heat transfer and flow pattern in electronic systems
- Bioheat and mass transfer
- Heat transfer and flow pattern in building elements
- Computational fluid dynamics and heat transfer
Supervisor’s
main publications
main publications
1) Bondareva N.S., Buonomo B., Manca O., Sheremet M.A. Heat transfer performance of the finned nano-enhanced phase change material system under the inclination influence // International Journal of Heat and Mass Transfer 135 (2019) 1063–1072
2) Mikhailenko S.A., Sheremet M.A., Pop I. Natural convection combined with surface radiation in a rotating cavity with an element of variable volumetric heat generation // Energy 210 (2020) 118543
3) Sheremet M.A., Rashidi M.M. Thermal convection of nano-liquid in an electronic cabinet with finned heat sink and heat generating element // Alexandria Engineering Journal 60(3) (2021) 2769–2778
4) Bondareva N.S., Sheremet M.A. Influence of PCM heat sink shape on cooling of heat-generating elements in electronics // Applied Thermal Engineering 213 (2022) 118695
5) Loenko D., Öztop H.F., Sheremet M.A. Cooling of a periodic heat-generating solid element in an electronic cabinet using a non-Newtonian pseudoplastic nanofluid and a heat-conducting substrate // International Journal of Numerical Methods for Heat and Fluid Flow 33(5) (2023) 1886–1899
6) Akulova D.V., Sheremet M.A. Mathematical Simulation of Bio-Heat Transfer in Tissues Having Five Layers in the Presence of a Tumor Zone // Mathematics. 2024. Vol. 12, № 5. Art. num. 676. URL: https://www.mdpi.com/2227-7390/12/5/676
7) Role of applying PCMs on thermal behavior of innovative unit roof enclosure / M.A. Sheremet, A. Hajjar, L.M.Q. Nguyen, M.B.B. Hamida [et al] // Journal of Energy Storage. 2024. Vol. 77. Art. num. 109918. DOI: 10.1016/j.est.2023.109918
8) Charging and discharging heat transfer improvement of shell-tube storage utilizing a partial layer of anisotropic metal foam / M. Sheremet, M. Ghalambaz, M. Bouzidi, K. Shank [et al] // Journal of Energy Storage. 2024. Vol. 79. Art. num. 109948. DOI: 10.1016/j.est.2023.109948
9) Deciphering Urban Heat Island Mitigation: A Comprehensive Analysis of Application Categories and Research Trends / M.A. Sheremet, M. Ghalambaz, Y. Qin, S. Galambaz [et al] // Sustainable Cities and Society. 2024. Vol. 101. Art. num. 105081. DOI: 10.1016/j.scs.2023.105081
10) The influence of aspect ratios of two elliptical cylinders on the solid-liquid phase change flow / M.A. Sheremet, N.B. Khedher, M. Ghodrat, A.M. Hussin [et al] // Alexandria Engineering Journal. 2024. Vol. 86. P. 346‒359. DOI: 10.1016/j.aej.2023.11.048
11) Turbulent cylindrical heat flow visualization in free convection regime / M.A. Sheremet, S.P. Suresha, G.J. Reddy, H. Basha [et al] // Indian Journal of Physics. 2024. Vol. 98, № 1. P. 301‒317. DOI: 10.1007/s12648-023-02779-9
12) Hussain M., Sheremet M., Farooq U., Jadoon A. Non-similar heat transfer analysis of magnetized flow of Ag-Mgo/water hybrid nanofluid flow through darcy porous medium // ZAMM - Journal of Applied Mathematics and Mechanics. 2024. Vol. 104, № 1. P. 0. DOI: 10.1002/zamm.202200628
13) Sheremet M.A., Rosca A.V., Rosca N.C., Pop I. Natural convection and entropy generation in a trapezoidal region with hybrid nanoliquid under magnetic field // International Journal of Numerical Methods for Heat & Fluid Flow. 2024. Vol. 34, № 2. P. 429‒450. DOI: 10.1108/HFF-04-2023-0193
2) Mikhailenko S.A., Sheremet M.A., Pop I. Natural convection combined with surface radiation in a rotating cavity with an element of variable volumetric heat generation // Energy 210 (2020) 118543
3) Sheremet M.A., Rashidi M.M. Thermal convection of nano-liquid in an electronic cabinet with finned heat sink and heat generating element // Alexandria Engineering Journal 60(3) (2021) 2769–2778
4) Bondareva N.S., Sheremet M.A. Influence of PCM heat sink shape on cooling of heat-generating elements in electronics // Applied Thermal Engineering 213 (2022) 118695
5) Loenko D., Öztop H.F., Sheremet M.A. Cooling of a periodic heat-generating solid element in an electronic cabinet using a non-Newtonian pseudoplastic nanofluid and a heat-conducting substrate // International Journal of Numerical Methods for Heat and Fluid Flow 33(5) (2023) 1886–1899
6) Akulova D.V., Sheremet M.A. Mathematical Simulation of Bio-Heat Transfer in Tissues Having Five Layers in the Presence of a Tumor Zone // Mathematics. 2024. Vol. 12, № 5. Art. num. 676. URL: https://www.mdpi.com/2227-7390/12/5/676
7) Role of applying PCMs on thermal behavior of innovative unit roof enclosure / M.A. Sheremet, A. Hajjar, L.M.Q. Nguyen, M.B.B. Hamida [et al] // Journal of Energy Storage. 2024. Vol. 77. Art. num. 109918. DOI: 10.1016/j.est.2023.109918
8) Charging and discharging heat transfer improvement of shell-tube storage utilizing a partial layer of anisotropic metal foam / M. Sheremet, M. Ghalambaz, M. Bouzidi, K. Shank [et al] // Journal of Energy Storage. 2024. Vol. 79. Art. num. 109948. DOI: 10.1016/j.est.2023.109948
9) Deciphering Urban Heat Island Mitigation: A Comprehensive Analysis of Application Categories and Research Trends / M.A. Sheremet, M. Ghalambaz, Y. Qin, S. Galambaz [et al] // Sustainable Cities and Society. 2024. Vol. 101. Art. num. 105081. DOI: 10.1016/j.scs.2023.105081
10) The influence of aspect ratios of two elliptical cylinders on the solid-liquid phase change flow / M.A. Sheremet, N.B. Khedher, M. Ghodrat, A.M. Hussin [et al] // Alexandria Engineering Journal. 2024. Vol. 86. P. 346‒359. DOI: 10.1016/j.aej.2023.11.048
11) Turbulent cylindrical heat flow visualization in free convection regime / M.A. Sheremet, S.P. Suresha, G.J. Reddy, H. Basha [et al] // Indian Journal of Physics. 2024. Vol. 98, № 1. P. 301‒317. DOI: 10.1007/s12648-023-02779-9
12) Hussain M., Sheremet M., Farooq U., Jadoon A. Non-similar heat transfer analysis of magnetized flow of Ag-Mgo/water hybrid nanofluid flow through darcy porous medium // ZAMM - Journal of Applied Mathematics and Mechanics. 2024. Vol. 104, № 1. P. 0. DOI: 10.1002/zamm.202200628
13) Sheremet M.A., Rosca A.V., Rosca N.C., Pop I. Natural convection and entropy generation in a trapezoidal region with hybrid nanoliquid under magnetic field // International Journal of Numerical Methods for Heat & Fluid Flow. 2024. Vol. 34, № 2. P. 429‒450. DOI: 10.1108/HFF-04-2023-0193
Supervisor’s
specific requirements
specific requirements
- programming languages (C++ or Fortran or others for computations)
- commercial CFD software (Fluent, Comsol Multiphysics) or open CFD software (OpenFOAM)
Research highlights
The proposed analysis will be performed using modern computational techniques (finite difference method, finite volume method, lattice Boltzmann method and others). For numerical simulation in-house computational codes will be developed. Investigations will be conducted in cooperation with foreign scientists from well-known foreign Universities.
