Your search keyword '"Gangadhar, Kotha"' showing total 13 results

1. EMHD Flow of Radiative Second-Grade Nanofluid over a Riga Plate due to Convective Heating: Revised Buongiorno’s Nanofluid Model

Author

Gangadhar, Kotha, Kumari, Manda Aruna, and Chamkha, Ali J.

Published

2022

2. Effects of Thermal Radiation and Magnetic Flux on MgO–Au–Ag/Blood Tri-Nanohybrid Fluid Flow in Arteries.

Author

Gangadhar, Kotha, Ananda Vardhana, K., Venkata Subba Rao, M., and Wakif, Abderrahim

Subjects

*HEAT radiation & absorption, *CONTROLLED release drugs, *ORDINARY differential equations, *BLOOD circulation, *DRUG delivery systems

Abstract

Nanoparticles such as magnesium oxide (MgO), silver (Ag) and gold (Au) can be used in conjunction with therapeutic agents, including anticancer drugs, gene therapy and antibiotics, to enable precise and controlled delivery. Recently, there has been significant interest in modifying biological fluid flow over arteries, particularly for drug delivery applications. This study aims to develop a comprehensive numerical model to investigate the flow dynamics of a hybrid nanofluid, specifically using pure blood as the base fluid and incorporating magnesium oxide (MgO), gold (Au) and silver (Ag) nanoparticles. The primary focus of this research is to explore the potential applications of this model in drug delivery systems, highlighting its promising capabilities for controlled and targeted drug release. The governing equations were transformed using the comparison transformation approach to address the system of nonlinear ordinary differential equations (ODEs). MATLAB’s BVP4C program was used to mathematically solve this problem and analyze the effects of relevant parameters. The findings show that the tri-hybrid nanofluid (MgO, Au and Ag) is extremely effective for heat control and medication transport within arterial channels. Specifically, under conditions of strong thermal radiation, the heat transfer rate at the lower wall increased by 83.924%, while at the upper wall, it increased by 72.098% for the tri-hybrid nanofluids. [ABSTRACT FROM AUTHOR]

Published

2024

3. Convective heat mechanism in Williamson nanoliquid over an escalating surface through an interface with viscous heating.

Author

Gangadhar, Kotha, Chandrika, G. Naga, and Wakif, Abderrahim

Subjects

*PROPERTIES of fluids, *AXIAL flow, *COLLOCATION methods, *HEAT radiation & absorption, *MAGNETIC fields

Abstract

This analysis explains the magneto-hydrodynamic flow on Williamson nanofluids previous stretching surface surrounded by the permeable media. The apt magnetic field was suggested for the angle of the axial direction of the flow. Anyhow, this flow phenomenon was characterized into the added heat source/sink and conjunction of radiating heat. The impacts of convective heating and viscous heating by expanding surface were again the significant feature of the analysis. This originality arises by the combination of the cross-diffusion effects of reverse behavior on the thermophoresis and Brownian motion. This form sketched into the aforesaid phenomenon was modified into the nonlinear ordinary form by the appropriate assumptions on comparison transformations. Therefore, the sets of equations were controlled for the numerical access using Lobatto-IIIa collocation method applicable to this Matlab bvp4c shooting process. This parametric performance of many components about their statistical values was given numerical imitations graphically by the rate coefficients in tabular forms. The validation and the compliance of the current result were acquired by the past study on the specific case. Further, the significant results of this analysis were: This non-Newtonian Williamson parameter combination of that magnetizing property diminishes the fluid velocities. In addition, the important influence of both viscosity parameter and radiation parameter of heating process was noted. [ABSTRACT FROM AUTHOR]

Published

2024

4. Generalized slip impact of Casson nanofluid through cylinder implanted in swimming gyrotactic microorganisms.

Author

Gangadhar, Kotha, Sujana Sree, T., and Wakif, Abderrahim

Subjects

*NONLINEAR boundary value problems, *NONLINEAR differential equations, *BROWNIAN motion, *PARTIAL differential equations, *RESISTIVE force

Abstract

In this paper, the self-propelled movement on gyrotactic swimming microorganisms into this generalized slip flow by nanoliquid over the stretching cylinder with strong magnetic field is discussed. Constant wall temperature was pretended as well as the Nield conditions of boundary. The intuitive non-Newtonian particulate suspension was included into applying Casson fluid by the base liquid and nanoparticles. This formation on the bio-mathematical model gives the boundary value problem by the nonlinear partial differential equations. Primly, modeled numerical system was converted to nondimensional against this help on acceptable scaling variables and the bvp4c technique was used to acquire the mathematical outcomes on the governing system. This graphical description by significant parameters and their physical performance was widely studied. The Prandtl number has the maximum contribution (112.595%) along the selected physical parameters, whereas the Brownian motion has the least (0.00165%) heat transfer rate. Anyhow, Casson fluid was established for much helpful suspension of this method on fabrication and coatings, etc. Therefore, this magnetic field performs like the resistive force of that fluid motion, and higher energy was enlarged into the structure exhibiting strong thermal radiation. [ABSTRACT FROM AUTHOR]

Published

2024

5. Effect of entropy minimization and melting heat on gold-magnesium oxide hybrid nanofluid in squeezing channel with magnetic field with radiation.

Author

Gangadhar, Kotha, Victoria, E. Mary, and Chamkha, Ali J.

Subjects

*NANOFLUIDS, *ENTROPY, *THERMAL boundary layer, *HEAT radiation & absorption, *MAGNETIC entropy, *MAGNETIC fields, *NUSSELT number, *HEAT transfer

Abstract

The principal aim of this investigation is to examine the gold and magnesium oxide hybrid nanoparticles in different physical capacities on the water-based hybrid nanofluid and elaborate on an erratic squeezing flow among both infinite plates. Melting effect and thermal radiation depict heat transfer features. Production of the Bejan number and entropy is upward. The explains the governing equations, and the standard transformation is supplied. The numerical solutions are carried out using an efficient finite element method. To analyze difference between heat transfer and its implication in industrial zone, the Nusselt number was arranged in a horizontal pattern. The results showed that a thicker thermal boundary layer increased the Eckert number and the volume fraction of gold nanoparticles. Anyhow, the heat transfer rate by Au–MgO/water was necessarily greater than the Au–water. The obtained results are excellent and vigorously oppose those that are applicable to the literature by the attached position. It was established for hybrid nanofluids to display higher entropy generation rates. The outcomes of this analysis were the consequence of the appraisal of the impact on few required form parameters in heat transfer and consequently on the expansion for industrial use. [ABSTRACT FROM AUTHOR]

Published

2024

6. Impact of the Stefan gusting on a bioconvective nanofluid with the various slips over a rotating disc and a substance-responsive species.

Author

Gangadhar, Kotha, Rao, M. Venkata Subba, Kumari, Manda Aruna, and Wakif, Abderrahim

Abstract

This paper presents thorough computational and theoretical analyses of steady forced convective flow over a rotating disc submerged in a water-based nanofluid containing microorganisms. It delves into the examination of boundary layer flow characteristics of a viscous nanofluid, considering Stefan blowing effects and multiple slip conditions influenced by a magnetic field. Notably, the study accounts for novel aspects such as thermal radiation and both constructive and destructive chemical reactions. The movement of nanoparticles is elucidated based on thermophoresis and microscopic behaviors, while changes in volume fraction do not affect the thermo-physical properties of the nanofluid. To address the altered nonlinear set of differential equations, an effective numerical approach, the Keller-Box method, is implemented for critical and efficient solutions. These appropriate transformations are defined and applied. When compared to blowing suction, it shows a better enhancement in the rate of heat transfer, mass, and microorganisms. Some of the main observations are there is a decrease in wall skin friction in the directions of radial and tangential as magnetic field strength is increased. The evaluation of thermal boundary layer thickness and temperature is noted for the radiation parameter (Rd) improvement. The present analysis has applications in electromagnetic micro-pumps and nanomechanics. As to the applications in the science and engineering fields, technologies such as micro-electromechanical systems-based microfluidic devices and microfluidic-related technologies will be accepted. [ABSTRACT FROM AUTHOR]

Published

2024

7. Multiple convected conditions in Williamson nanofluidic flow with variable thermal conductivity: Revised bioconvection model.

Author

Gangadhar, Kotha, Rupa Lavanya, M., and Chamkha, Ali J.

Subjects

*ORDINARY differential equations, *NONLINEAR differential equations, *SOLAR thermal energy, *HEAT radiation & absorption, *PECLET number, *FREE convection, *THERMAL conductivity

Abstract

The importance of bioconvection into the application of nanoparticles has had a significant impact on fundamental technological and industrial functions in recent years. These discussions are being carried forward by the bioconvection appearance on that flow by attracting nanoparticles into additional features on thermal radiation and activation energy. The investigation had been proposed on the appealing features of the mass and thermal convective boundary constraints. The high desirable subclass on rate-type fluid, especially Williamson fluid, was used to anticipate the absolute rheological parameters. The designated partial differential system was modified along with nonlinear ordinary differential equations applying enhance being related conversion, the designated partial differential system was modified along nonlinear ordinary differential equations. The governing equations are interpreted into ordinary differential equations, and in the following, shooting process was obeyed to build up the mathematical classification on the convert dimensionless flow problem. This value of physical restraint was displayed on the table and plots tests. This noted theoretical imitation could be highly successful in improving the solar energy systems and thermal extrusion processes. The outcomes reported that the rise in Weissenberg number and Hartmann number decreased the nanoparticles velocity distribution. The progressing temperature distribution was observed to develop radiation parameter and thermal conductivity parameter. That was further noted to modify bioconvection Lewis number and Peclet number that were reduced into motile microorganism distribution effectively. [ABSTRACT FROM AUTHOR]

Published

2024

8. Binary chemical interaction and nonlinearity radiative flux of Williamson fluidic flow through Riga plate.

Author

Gangadhar, Kotha, Sujana Sree, T., and Chamkha, Ali J.

Abstract

This Riga plate, which extends the configuration with permanent magnets and electrodes, may induce a wall-parallel Lorentz force over the magnetic field and exterior electrics, enabling efficient control of the fluid flow. In this paper, the focus is on considering the three-dimensional flow characteristics of Williamson fluid past the Riga plate in the absence of variable thermal properties. Many influential factors, such as convective boundary conditions of temperature, viscous dissipation, binary chemical reactions, and thermal radiation, are studied in their analysis. To address the study problem, dimensionless parameters are used to clarify the conductive partial differential equations. This dimensionless form was consequently determined mathematically by applying the shooting technique. The affected engineering parameters were interpreted graphically to appeal to physical interest. It was observed that the velocity distribution slows down into the viscosity parameter and stretching ratio constant. The enhanced temperature distribution was noticed in the increase in the thermal conductivity parameter. The rate of heat transport (130.56%) rises in the presence of Biot numbers. This causes significant increases in convective heat transport and heat energy. [ABSTRACT FROM AUTHOR]

Published

2024

9. Thermally radiated micro-polar fluid with space-dependent heat source: Modified Cattaneo-Christov heat flux theory.

Author

Gangadhar, Kotha, Prameela, Macharla, and Chamkha, Ali J.

Abstract

The principle aim is to investigate the micro-inertia for vertex viscosity effects that were utilized about design to act on heat energy. Heat transfer was imposed out that unsteady distributed stagnation point flow by micro-polar fluid. That define the energy equation, Cattaneo-Christov heat flux figure was used for formal Fourier's law. Effects on exponential space-dependent heat source and linear thermal radiation were more comprise on the interpreted model. Numerical technique finite element method was occupied about the results to ordinary differential equations that were acquired against governing partial differential equations below the convenient equal transformations. This flow reach toward the departure domain displayed the absorbed flow aspect and opposite flow aspect susceptible on that physical parameters elaborate into the analysis. In view of acquired results, we observed that thermal profile downturn about extra sizably higher values of relaxation time, during increase into increasing radiation factor. An increase in vertex viscosity increases angular motion. Moreover, space-dependent heat digestion is extra applicable about cooling process. That more, the acceptance of current results was entire as growing analogy into actual circulated work. [ABSTRACT FROM AUTHOR]

Published

2023

10. Buoyancy flow of nanohybrid fluid over a rotating sphere imperiled to convective and viscous heating.

Author

Gangadhar, Kotha, Venkata Krishna Sarma, Swayampakula, and Chamkha, Ali J.

Subjects

*ROTATING fluid, *FLUID flow, *STAGNATION flow, *HEAT radiation & absorption, *STAGNATION point, *BUOYANCY, *FREE convection, *CONVECTIVE flow

Abstract

The thermal radiation and convective condition principles were working on specific functions like gas turbines, electrical fuel, renewable energy, projectiles, nuclear power plants, aerospace engineering, and thermal transportation. Considering the aforementioned functions, the present analysis inspected the stagnation point hybrid nanofluids movement over the rotating sphere on the behavior of viscous dissipation and thermal radiation. Silver and Ferrous nanoparticles including the host fluid water were held into affected the flow. The presence of convective boundary conditions is incorporated within the system. Applying appropriate correspondence factors, nonlinear governing equations were transformed with ordinary differential equations. This finite element method is applied to find the mathematical solutions to the boundary conditions and simplified equations. These outcomes convey to temperature was decreased about accelerated factor, although primary velocity was found into increased. The heat transfer was magnified by thermal Biot number, and that rate of development was greater about hybrid nanosuspension. The heat transport method was reduced by the Eckert number; also that reduction rate was similarly dull on hybrid. [ABSTRACT FROM AUTHOR]

Published

2023

11. Slippery boundary and radiative transport in unsteady features of Maxwell fluid over stretched cylinder.

Author

Subbarao, K., Elangovan, K., and Gangadhar, Kotha

Abstract

This article employs the Cattaneo-Christov double diffusion concept to examine thermal and solute energy transfer processes in Maxwell liquid movement. The irregular two-dimensional movement of a Maxwell liquid with changing heat conductivity across an extended cylinder is investigated, together with thermal radioactivity and velocity slip. We develop partial differential equations for heat and mass transmission in Maxwell liquid using the Cattaneo-Christov pattern instead of Fourier's and Fick's law. Numerical shooting solves ordinary differential equations obtained from controlling partial differential equations via similarity transformations. We noticed that unstable factor should be no more than one for optimal outcomes. Greater Maxwell values minimize the movement field and increase liquid energy transfer. Heat and concentration diffusions in Maxwell liquids decline as thermal and concentration relaxation times approach maximum. In addition, a low thermal conductivity characteristic improves the temperature field. [ABSTRACT FROM AUTHOR]

Published

2023

12. Effect of thermal radiation on engine oil nanofluid flow over a permeable wedge under convective heating

Author

S.M. Ibrahim, Keziya Kukkamalla, and Gangadhar Kotha

Subjects

Materials science, Biot number, Mechanical Engineering, Heat transfer enhancement, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Boundary layer, 020303 mechanical engineering & transports, Nanofluid, 0203 mechanical engineering, Mechanics of Materials, Thermal radiation, Parasitic drag, Drag, Modeling and Simulation, Heat transfer, General Materials Science, 0210 nano-technology

Abstract

Purpose The purpose of this paper is to examine the magneto hydrodynamic flow and heat transfer of nanofluids over a permeable wedge based on engine oil which is under the effects of thermal radiation and convective heating. Design/methodology/approach The equations governing the flow are transformed into differential equations by applying similarity transformations. Keller box method is used to bring out the numerical solution. Findings The discovery interprets that temperature as well as the velocity of Ag-engine oil nanofluids are more noticeable than Cu-engine oil nanofluids. Thermal boundary layer increases for radiation parameter as well as Biot number. Fluctuations of co-efficient of drag skin friction as well heat transfer rate at the wall are also tested. Originality/value Till now, no numerical studies are reported on the heat transfer enhancement of the permeable wedge under thermal radiation on engine oil nanofluid flow by considering convective heating.

Published

2019

13. Effects of Newtonian heating and thermal radiation on micropolar ferrofluid flow past a stretching surface: Spectral quasi‐linearization method.

Author

Gangadhar, Kotha, Vijayakumar, Damerla, Chamkha, Ali J., Kannan, Thangavelu, and Sakthivel, Gnanasekaran

Subjects

*MICROPOLAR elasticity, *HEAT radiation & absorption, *QUASILINEARIZATION, *HEAT, *ORDINARY differential equations, *NONLINEAR differential equations, *FERRIC oxide

Abstract

This study article addresses the flow and heat transfer characteristics of a magnetite Fe3O4 micropolar ferrofluid flow past a stretching sheet. For practical interest, thermal radiation, Newtonian heating, and a heat source or sink are considered in this investigation. A useful Tiwari‐Das nanofluid model is considered to analyze the microstructure and inertial characteristics of the water‐based nanofluids containing iron oxide. The dimensionless nonlinear ordinary differential equations are solved by employing suitable similarity variables. The resulting nonlinear system is solved by the spectral quasi‐linearization method. The effects of different nondimensional parameters on various profiles are shown graphically and explored in detail. It is found that the micropolar ferrofluid exhibits a higher energy distribution than that of a classical micropolar fluid. Compared to the classical micropolar liquid, local skin-friction is more significant for the micropolar magnetite ferrofluid. In the presence of Newtonian heating, the thermal behavior of the micropolar nanofluid is remarkably better than that of the classical micropolar fluid. [ABSTRACT FROM AUTHOR]

Published

2020