830 results on '"Pantokratoras, Asterios"'
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102. Comment on the paper “Effects of Thermal Radiation and Slip Mechanism on Mixed Convection Flow ofWilliamson Nanofluid Over an Inclined Stretching Cylinder, Masood Khan, Aamir Hamid, Hashim, Communications in Theoretical Physics, 71(2019), 1405-1415”
103. Comment on the paper “One-parameter lie scaling study of carreau fluid flow with thermal radiation effects, Musharafa Saleem, Qasim Ali Chaudhry, A. Othman Almatroud, Chaos, Solitons and Fractals 148 (2021) 110996”
104. Steady laminar assisted mixed convection normally to a heated horizontal plate with finite length
105. CFD methodology for sedimentation tanks: The effect of secondary phase on fluid phase using DPM coupled calculations
106. Buoyancy effects on thermal boundary layer over a vertical plate with a convective surface boundary condition: new results
107. A note on MHD Blasius flow
108. Comment on the paper “Microfluidic on-demand particle separation using induced charged electroosmotic flow and magnetic field” by Mohammad Alipanah, Mohammad Hafttananian, Nima Hedayati, Abas Ramiar, Morteza Alipanah, Journal of Magnetism and Magnetic Materials 537(2021), 168156
109. Comment on the paper “Rheological behaviors and model of fresh concrete in vibrated state, Zhuguo Li, Guodong Cao, Cement and Concrete Research 120(2019) 217–226”
110. Comment on the paper “Microsystem Technologies, https://doi.org/10.1007/s00542-018-3996-x”
111. Comment on the paper "an explicit‐implicit numerical scheme for time fractional boundary layer flows, International Journal for Numerical Methods in Fluids, 2022, 94:920–940".
112. Note on the effect of thermal radiation in the linearized Rosseland approximation on the heat transfer characteristics of various boundary layer flows
113. Comments to papers “Unsteady MHD flow with variable viscosity: Applications of spectral scheme”, by M. Turkyilmazoglu, International Journal of Thermal Sciences, 49 (2010), 563–570 and “Thermal radiation effects on time-dependent MHD permeable flow having variable viscosity”, by M. Turkyilmazoglu, International Journal of Thermal Sciences, 50 (2011), 88–96
114. Comment on the paper “Generalized magnetic blood flow in a cylindrical tube with magnetite dusty particles, Muhammad Saqib, Ilyas Khan, Sharidan Shafie, Journal of Magnetism and Magnetic Materials 484 (2019) 490–496”
115. Comment on the paper “MHD slip flow of a dissipative Casson fluid over a moving geometry with heat source/sink: A numerical study, C.S.K. Raju, N. Sandeep, Acta Astronautica 133 (2017) 436–443”
116. Comment on the paper “Comprehensive analysis of fluid-particle interactions in a liquid-solid fluidized bed via CFD-DEM coupling and tomography, Hussein Zbib, Mohammadreza Ebrahimi, Farhad Ein-Mozaffari, Powder Technology, 340 (2018), 116-130”
117. Confined and unconfined mixed convection flow past a rigid cube enclosed in a rectangular channel
118. Comment on the “Corrigendum to “Wavelet based numerical approach of non-classical moving boundary problem with convection effect and variable latent heat under the most generalized boundary conditions” [Eur.J. Mech.B Fluids 87 (2021) 1-11], Jitendra, K.N.Rai, Jitendra Singh, European Journal of Mechanics B/Fluids 90 (2021) 63”
119. Mixed Convection in a Darcy–Brinkman Porous Medium with a Constant Convective Thermal Boundary Condition
120. Blasius flow with non-linear Rosseland thermal radiation
121. The forced convection flow over a flat plate with finite length with a constant convective boundary condition
122. Discussion on the paper “Theoretical study of micropolar hybrid nanofluid over Riga channel with slip conditions, Nadeem Abbas, S. Nadeem, M.Y. Malik, Physica A 551 (2020) 124083”
123. Magnetohydrodynamic flow with viscous dissipation effects in the presence of suction and injection. New results
124. Comment on the paper "A new LRBFCM-GBEM modeling algorithm for general solution of time fractional-order dual phase lag bioheat transfer problems in functionally graded tissues," Mohamed Abdelsabour Fahmy, Numerical Heat Transfer, Part A: Applications 2019, vol. 75, no. 9, pp. 616-626
125. Discussion on the paper “A Numerical Scheme for Fractional Mixed Convection Flow Over Flat and Oscillatory Plates, Yasir Nawaz, Muhammad Shoaib Arif, Kamaleldin Abodayeh, Journal of Computational and Nonlinear Dynamics, July 2022, Vol. 17, 071008”
126. Discussion on the paper “On magnetohydrodynamics Prandtl fluid flow in the presence of stratification and heat generation, Imad Khan, Arif Hussain, M.Y. Malik, Safyan Mukhtar, Physica A 540 (2020) 123008”
127. Comment on the paper “Wall effects for spherical particle in confined shear-thickening fluids, Shuai Tian, Journal of Non-Newtonian Fluid Mechanics 257(2018) 13–21”
128. Comment on the paper “On stagnation point flow of Sisko fluid over a stretching sheet, Masood Khan, Azeem Shahzad, Meccanica (2013) 48:2391–2400”
129. Comment on the paper “Modeling 3D conjugate heat and mass transfer for turbulent air drying of Chilean papaya in a direct contact dryer, Roberto A. Lemus-Mondaca, Antonio Vega Galvez, Carlos E. Zambra, Nelson O. Moraga, Heat Mass Transfer, 2017, 53:11-24”
130. Comment on the Paper “Onset of Marangoni-Bénard Ferroconvection with Temperature Dependent Viscosity, C. E. Nanjundappa, I. S. Shivakumara, R. Arunkumar, Microgravity Sci. Technol. (2013) 25:103–112”
131. Comment on the paper “Transient MHD free convective flow past an infinite vertical plate embedded in a porous medium with viscous dissipation, Siva Reddy Sheri, R. Srinivasa Raju, Meccanica, DOI 10.1007/s11012-015-0285-y”
132. Comment on the paper Ferroconvection in a porous medium with vertical throughflow, C. E. Nanjundappa · Rafael Tadmor, Acta Mech. 226, 1515–1528 (2015)
133. The nonsimilar laminar wall jet with uniform blowing or suction: New results
134. Further results on non-Newtonian power-law flows past a two-dimensional flat plate with finite length
135. Comment on the paper “A new analytical approach for the research of thin‐film flow of magneto hydrodynamic fluid in the presence of thermal conductivity and variable viscosity, Liaqat Ali, Asifa Tassaddiq, Rohail Ali, Saeed Islam, Taza Gul, Poom Kumam, Safyan Mukhtar, Noor Saeed Khan, Phatiphat Thounthong, ZAMM, 2021;101:E201900292”
136. Comment on Ali et al. 2017
137. Comment on the paper “Comparative investigation of five nanoparticles in flow of viscous fluid with Joule heating and slip due to rotating disk, Sumaira Qayyum, Muhammad Ijaz Khan, Tasawar Hayat, Ahmed Alsaedi, Physica B: Condensed Matter 534 (2018) 173–183”
138. Comment on the paper " AIChE Journal, Vol. 63, 5149-5158, 2017''
139. Forced convection heat transfer from a heated rotating sphere in laminar flow revisited
140. Blasius and Sakiadis flow with suction and non-linear Rosseland thermal radiation
141. Comment on the paper “Impact of variable thermal conductivity in doubly stratified chemically reactive flow subject to non-Fourier heat flux theory, T. Hayat, M. Zubair, M. Waqas, A. Alsaedi, M. Ayub, Journal of Molecular Liquids 234 (2017) 444–451”
142. Convection in the Rayleigh-Bénard flow with all fluid properties variable
143. A note on the Blasius and Sakiadis flow of a non-Newtonian power-law fluid in a constant transverse magnetic field
144. Comment on “Thermal radiation effects on MHD flow of a micropolar fluid over a stretching surface with variable thermal conductivity”, by Mostafa A.A. Mahmoud [Physica A 375 (2007) 401–410]
145. Forced Convection Flow of Power-Law Fluids Over a Flat Plate Embedded in a Darcy-Brinkman Porous Medium
146. Flow of a Weakly Conducting Fluid in a Channel Filled with a Porous Medium
147. Nonsimilar aiding mixed convection along a moving cylinder
148. Comment on the paper "Fractional viscoelastic models with non-singular kernels, Long Jianmin, Xiao Rui, Chen Wen, Mechanics of Materials 127(2018) 55-64”
149. Comment on the paper “A computational wavelet method for variable-order fractional model of dual phase lag bioheat equation, M. Hosseininia, M.H. Heydari, R. Roohi, Z. Avazzadeh, Journal of Computational Physics 395 (2019) 1-18”
150. Flow Adjacent to a Stretching Permeable Sheet in a Darcy–Brinkman Porous Medium
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