M.Y. Malik

What is he best known for?

The fields of study he is best known for:

• Mechanics
• Thermodynamics
• Fluid dynamics

The scientist’s investigation covers issues in Mechanics, Boundary layer, Nanofluid, Nusselt number and Heat transfer. His study in the field of Prandtl number and Stagnation point is also linked to topics like Materials science. M.Y. Malik has included themes like Cylinder, Mathematical analysis and Ordinary differential equation in his Boundary layer study.

His work on Sherwood number as part of general Nusselt number research is often related to Heat generation, thus linking different fields of science. His work in Heat transfer addresses issues such as Thermal conductivity, which are connected to fields such as Thermal conduction and Heat transfer coefficient. The concepts of his Classical mechanics study are interwoven with issues in Flow, Partial differential equation and Fluid dynamics.

His most cited work include:

• MHD flow of Cattanneo–Christov heat flux model for Williamson fluid over a stretching sheet with variable thickness: Using numerical approach (98 citations)
• MHD flow of tangent hyperbolic fluid over a stretching cylinder: Using Keller box method (93 citations)
• Mixed convection flow of MHD Eyring-Powell nanofluid over a stretching sheet: A numerical study (90 citations)

What are the main themes of his work throughout his whole career to date?

His scientific interests lie mostly in Mechanics, Materials science, Flow, Heat transfer and Nanofluid. His research in Mechanics intersects with topics in Nusselt number and Partial differential equation. His work carried out in the field of Partial differential equation brings together such families of science as Shooting method, Carreau fluid and Ordinary differential equation.

His Flow study combines topics in areas such as Work, Cylinder, Magnetohydrodynamics, Viscosity and Classical mechanics. M.Y. Malik has included themes like Fin, Thermal conduction, Fourier transform and Homotopy analysis method in his Heat transfer study. His Nanofluid research incorporates elements of Brinkman number and Newtonian fluid.

He most often published in these fields:

• Mechanics (106.51%)
• Materials science (44.44%)
• Flow (39.85%)

What were the highlights of his more recent work (between 2019-2021)?

• Mechanics (106.51%)
• Materials science (44.44%)
• Nanofluid (39.46%)

In recent papers he was focusing on the following fields of study:

His primary areas of study are Mechanics, Materials science, Nanofluid, Heat transfer and Partial differential equation. His work deals with themes such as Nusselt number, Magnetohydrodynamics and Cylinder, which intersect with Mechanics. His biological study spans a wide range of topics, including Combined forced and natural convection, Brinkman number, Homotopy analysis method and Boundary layer.

His work in the fields of Heat transfer, such as Heat flux and Stagnation point, intersects with other areas such as Heat generation. M.Y. Malik works mostly in the field of Partial differential equation, limiting it down to topics relating to Ordinary differential equation and, in certain cases, Dimensionless quantity and Curvature. M.Y. Malik has researched Fluid dynamics in several fields, including Surface and Prandtl number.

Between 2019 and 2021, his most popular works were:

• Inspection of hybrid based nanofluid flow over a curved surface. (41 citations)
• Transportation of magnetized micropolar hybrid nanomaterial fluid flow over a Riga curface surface (34 citations)
• Numerical analysis of water based CNTs flow of micropolar fluid through rotating frame. (29 citations)

In his most recent research, the most cited papers focused on:

• Mechanics
• Thermodynamics
• Geometry

M.Y. Malik mainly investigates Mechanics, Nanofluid, Heat transfer, Ordinary differential equation and Partial differential equation. His study in the fields of Flow and Fluid dynamics under the domain of Mechanics overlaps with other disciplines such as Materials science and Joule heating. His Nanofluid research includes elements of Nusselt number, Stagnation point and Boundary layer.

The Heat transfer study combines topics in areas such as Numerical analysis and Finite element method. His research investigates the connection with Ordinary differential equation and areas like Dimensionless quantity which intersect with concerns in Boundary layer thickness and Mathematical analysis. His work in Partial differential equation covers topics such as Curvature which are related to areas like Carreau fluid and Magnetic Prandtl number.

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