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182 results on '"Behera, Harekrushna"'

1. Instability behavior of odd viscosity-induced viscous fluid over a vibrating bed

Author

Hossain, Md. Mouzakkir, Saha, Mrityunjoy, Behera, Harekrushna, and Ghosh, Sukhendu

Subjects
Physics - Fluid Dynamics
Abstract

The manuscript focuses on the theoretical stability analysis of the viscous liquid over a vibrating inclined rigid bed when the fluid undergoes an impact of odd viscosity. Such an impact emerges in the classical fluid owing to the broken time-reversal symmetry. The rigid bottom vibrates in streamwise and cross-stream directions. The time-dependent Orr-Sommerfeld eigenvalue problem is obtained using the normal mode approach and resolved based on the Chebyshev-collocation method and the Floquet theory. The effect of the odd viscosity coefficient on the different types of instability gravitational, subharmonic, and harmonic are identified. The gravitational instability arises in the longwave region, whereas the resonated wave instability appears in the finite wavenumber region. The gravitational instability is generated in the fluid flow owing to the gravity driving force, whereas the subharmonic instability appears for lower forcing amplitude and the harmonic instability emerges for comparatively higher forcing amplitude. It is found that the subharmonic and harmonic resonances appear when the forcing amplitude surpasses its critical value. A higher odd viscosity leads to stabilizing the gravitational instability, whereas a larger odd viscosity diminishes the subharmonic resonance along with the harmonic resonance instigated at a high forcing amplitude. Further, a new instability, named shear instability in the finite wavenumber range emerges together with the aforementioned three instabilities when the Reynolds number is sufficiently high with a low angle of inclination and becomes weaker when the time-reversal symmetry breaks., Comment: 16 pages, 22 figures

Published
2024

2. Hydrodynamic instability of shear imposed falling film over a uniformly heated inclined undulated substrate

Author

Hossain, Md. Mouzakkir, Ghosh, Sukhendu, Behera, Harekrushna, and Sekhar, G. P. Raja

Subjects
Physics - Fluid Dynamics
Abstract

Linear and weakly nonlinear stability analyses of an externally shear-imposed, gravity-driven falling film over a uniformly heated wavy substrate are studied. The longwave asymptotic expansion technique is utilized to formulate a single nonlinear free surface deflection equation. The linear stability criteria for the onset of instability are derived using the normal mode form in the linearized portion of the surface deformation equation. Linear stability theory reveals that the flow-directed sturdy external shear grows the surface wave instability by increasing the net driving force. On the contrary, the upstream-directed imposed shear may reduce the surface mode instability by restricting the gravity-driving force, which has the consequence of weakening the bulk velocity of the liquid film. However, the surface mode can be stabilized/destabilized by increasing the temperature-dependent density/surface-tension variation. Further, the bottom steepness shows dual behaviour on the surface instability depending upon the wavy wall's portion (uphill/downhill). At the downhill portion, the surface wave becomes more unstable than at the bottom substrate's uphill portion. Moreover, the multi-scale method is incorporated to obtain the complex Ginzburg-Landau equation in order to study the weakly nonlinear stability, confirming the existence of various flow regions of the liquid film. At any bottom portion (uphill/downhill), the flow-directed external shear expands the super-critical stable zones, which causes an amplification in the nonlinear wave amplitude, and the backflow-directed shear plays a counterproductive role. On the other hand, the super-critical stable region decreases or increases as long as the linear variation of density or surface tension increases with respect to the temperature, whereas the sub-critical unstable region exhibits an inverse trend., Comment: 29 pages, 46 figures, and 5 tables

Published
2024

4. Impact of a floating flexible plate on the stability of double-layered falling flow

Author

Hossain, Md. Mouzakkir, Ghosh, Sukhendu, and Behera, Harekrushna

Subjects
Physics - Fluid Dynamics
Abstract

The hydrodynamic stability behaviour of a two-layer falling film is explored with a floating flexible plate on the top surface. The stress balance at the surface is modeled using a modified membrane equation. There is an insoluble surfactant at the liquid-liquid interface of the flow system. The linear instability of perturbation waves is captured by numerically solving the generalized Orr-Sommerfeld eigenvalue problem using Chebyshev spectral collocation technique. Four different types of linear stability modes are identified: namely surface mode (SM), interface mode (IM), interface surfactant mode (ISM), and shear mode (SHM). The floating flexible plate has an inferior impact on all the existing modes in the longwave zone. However, a significant influence is noticed for the finite wave numbers. The surface and interface wave instabilities can be suppressed in the smaller wavenumber zone by imposing higher structural rigidity and uniform thickness of the flexible plate. The stabilizing nature of the surface mode becomes more powerful when the top layer viscosity is dominant. A new interfacial instability emerges when the top layer is less viscous than the lower one. At moderate Reynolds numbers, the behaviour of interface mode is different in two different zones $mr<1$ and $mr>1$, where $m$ and $r$ denote the viscosity and density ratio, respectively. Further, the unstable shear modes induced by the top and bottom layers are detected under the low inclination angles with a strong inertia force. The occurrence of the shear modes demands the bottom layer's viscosity and density to be very high than that of the upper layer. The influence of characteristic parameters of the flexible plate on the lower layer shear mode is not very sensitive. Finally, the competition between the different modes for dominance of stability boundaries is also discussed., Comment: 22 pages, 48 figures

Published
2023

5. Odd-viscosity induced surfactant-laden shear-imposed viscous film over a slippery incline

Author

Hossain, Md. Mouzakkir, Ghosh, Sukhendu, and Behera, Harekrushna

Subjects
Physics - Fluid Dynamics
Abstract

This research focuses on the stability analysis of an odd viscosity-induced shear-imposed Newtonian fluid flowing down an inclined slippery bed having an insoluble surfactant at the top of the liquid surface. The Orr-Sommerfeld boundary value problem is developed by applying the normal mode approach to the infinitesimal perturbed fluid flow and solved using the numerical method Chebyshev spectral collocation. The numerical results confirm the existence of Yih mode and Marangoni mode in the longwave zone. For the clean/contaminated surface of the film flow, the presence of an odd or Hall viscosity coefficient reduces the surface wave energy and delays the transition from laminar to perturbed flow. Also, it has stabilizing nature on the unstable Marangoni mode as well. The growth rate of both clean and contaminated liquid surfaces becomes more/less when the stronger external shear acts along the downstream/upstream direction of fluid flow. Further, the slip parameter leads to a lower critical Reynolds number and makes the liquid surface more unstable. An increase in the critical Reynolds number due to the stronger Marangoni force ensures that the insoluble surfactant has the potential to dampen the Yih mode instability. Moreover, the unstable shear mode occurs in the finite wavenumber regime with very high inertial force and a small angle of inclination. The two-fold variation of the shear mode instability is possible with respect to the imposed shear. However, the inclusion of the odd viscosity coefficient in the viscous falling film may advance the shear mode instability., Comment: 19 pages, 48 figures

Published
2023

12. Surface wave scattering by multiple flexible fishing cage system

Author

Selvan, Siluvai Antony, Gayathri, R., Behera, Harekrushna, and Meylan, Michael H

Subjects
Physics - Fluid Dynamics
Abstract

A study of the wave dynamics around a multiple fishing cage system is carried out under the assumption of the linear water wave theory and small-amplitude wave response. The Fourier--Bessel series expansion of the velocity potential is derived for regions enclosed under the open-water and cage systems and in the immediate vicinity. Further, the scattering between the cages is accounted for by employing Graf's addition theorem. The porous flexible cage system is modelled using Darcy's law and the three-dimensional membrane equation. The edges of the cages are moored along its circumferences to balance its position in the deep sea. The unknown coefficients in the potentials are obtained by employing the matched eigenfunction method in conjunction with the least-squares approximation method. In addition, the far-field scattering coefficients for the entire system are obtained by expanding the Bessel and Hankel functions in the plane wave representation form. Numerical results such as the hydrodynamic forces, scattering coefficients, and power dissipation are investigated for various cage and wave parameters. The wave loading on the cage system can be significantly damped by the spatial arrangement, membrane tension, and porous-effect parameter. Moreover, the far-field results suggest that the cage system can also be used as a breakwater.

Published
2020
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13. Impact of sloping porous seabed on the efficiency of an OWC against oblique waves

Author

Khan, Mohamin B M and Behera, Harekrushna

Subjects
Physics - Fluid Dynamics, Physics - Atmospheric and Oceanic Physics
Abstract

The study examines the influence of a sloping porous bed on the efficiency of an oscillating water column (OWC) device facing oblique water waves. A vertical, surface piercing, thin plate near a rigid wall approximates the OWC. The system is simulated using a multi-domain boundary element method assuming the linear potential theory. The impact of varying sloping bed structural parameters and influence of the incident wave angle on the performance of the OWC is evaluated and discussed. The significance of this model to act as a breakwater protecting near-shore marine facilities is also highlighted. The OWC efficiency is found to be highly sensitive to the slope of the porous seabed, and seabed porosity is found to stabilize the resonant frequency against changes in water levels. OWCs are found to be more efficient over porous seabeds with higher frictional coefficients. The results indicate optimum values for the parameters governing such a wave energy conversion system that can be used for the design and implementation of the model.

Published
2020
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14. Effect of imposed shear on the dynamics of a contaminated two-layer film flow down a slippery incline

Author

Sani, Muhammad, Selvan, Siluvai Antony, Ghosh, Sukhendu, and Behera, Harekrushna

Subjects
Physics - Fluid Dynamics
Abstract

The linear instability of a surfactant-laden two-layer falling film over an inclined slippery wall is analyzed under an influence of external shear which is imposed on the top surface of the flow. The free surface of the flow as well as the interface among the fluids are contaminated by insoluble surfactants. Dynamics of both the layers are governed by the Navier--Stokes equations, and the surfactant transport equation regulates the motion of the insoluble surfactants at the interface and free surface. Instability mechanisms are compared by imposing the external shear along and opposite to the flow direction. A coupled Orr--Sommerfeld system of equations for the considered problem is derived using the perturbation technique and normal mode analysis. The eigenmodes corresponding to the Orr--Sommerfeld eigenvalue problem are obtained by employing the spectral collocation method. The numerical results imply that the stronger external shear destabilizes the interface mode instability. However, a stabilizing impact of the external shear on the surface mode is noticed if the shear is imposed in the flow direction, which is in contrast to the role of imposed external shear on the surface mode for a surfactant laden single layer falling film. Moreover, the impression of shear mode on the primary instability is analyzed in the high Reynolds number regime with sufficiently low inclination angle. Under such configuration, dominance of the shear mode over the surface mode is observed due to the weaker impact of the gravitation force on the surface instability. The shear mode can also be stabilized by applying the external shear in the counter direction of the streamwise flow. Conclusively, the extra imposed shear on the stratified two-layer falling film plays an active role to control the attitude of the instabilities.

Published
2020
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15. Effect of floating flexible plate on the dynamics of flow over a mild-slope

Author

Selvan, Siluvai Antony, Ghosh, Sukhendu, Behera, Harekrushna, and Meylan, Michael H.

Subjects
Physics - Fluid Dynamics
Abstract

Hydrodynamic instability of a gravity-driven flow down an inclined plane is investigated in the presence of a floating elastic plate which rests on the top surface of the flow. Linear instability of the system with respect to infinitesimal disturbances is captured using normal-mode analysis. The critical conditions for instability are obtained analytically utilizing the long-wave approximation and small film aspect ratio. Further, the bifurcation of the nonlinear evolution equation is analyzed using weakly nonlinear stability analysis. The Orr-Sommerfeld system for the perturbed flow is derived, and it is solved numerically using the spectral collocation method. The behaviour of the marginal stability curves and temporal growth of the unstable waves are portrayed for a range of dimensionless flow parameters. Moreover, the pressure acting on the surface and shearing stress are calculated and analysed for various structural and flow configurations. The study reveals that critical structural parameters such as rigidity and mass per unit length play a crucial role in suppressing and facilitating the unstable surface waves of the flow. Numerical observations imply that the floating elastic plate helps to stabilize the surface flow and to damp the high amplitude waves., Comment: 25 pages, 21 figures

Published
2020

19. Evaluation of oscillating water column efficiency in the presence of multiple bottom-standing breakwaters under oblique waves.

Author

Venkateswarlu, V., Panduranga, Kottala, Vijay, K. G., and Behera, Harekrushna

Abstract

This study proposed an array of bottom-standing breakwaters (BSBs) in the presence of an oscillating water column (OWC) for a better understanding of physical mechanisms, under the framework of a linearized potential flow theory. The free water regions are provided between the multiple BSBs to utilize the gap resonance for energy extraction by OWC. The multi-domain boundary element method is adopted to conduct the parametric study, and the validation of the proposed model is presented. The effect of BSB physical properties, OWC, and incident wave properties are reported on the variation of OWC efficiency, radiation susceptance, conductance, force on the wall, and wave reflection by BSBs against the relative wave frequency and water depth. A comparative study on the variation of coefficients is presented between three types of BSB and flat seabed. The higher number of BSBs enhances the intensity of harmonics and subharmonics of coefficients and strengthens the harmonic trough of efficiency. The Bragg reflection by multiple BSBs diminishes the efficiency of OWC for particular wavelength, and the Bragg peak is suppressed by adopting the permeable property for BSBs. The enlargement of OWC efficiency toward the higher frequencies is observed with an increase in BSB height, width, and chamber length. This study suggests a pair of BSBs with a chamber length equal to water depth for optimal efficiency. Overall, the seaside inclined lip-wall, moderate chamber length, and double BSBs are recommended to diminish the Bragg peak (nearly 18%) and extract the maximum renewable energy for a wider frequency, from the OWC device against the incident waves. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Dehydrated Biomimetic Membranes with Skinlike Structure and Function

Author

Oh, Hyeonji, primary, Tu, Yu-Ming, additional, Samineni, Laximicharan, additional, De Respino, Sophie, additional, Mehrafrooz, Behzad, additional, Joshi, Himanshu, additional, Massenburg, Lynnicia, additional, Lopez-Marques, Horacio, additional, Elessawy, Nada, additional, Song, Woochul, additional, Behera, Harekrushna, additional, Dhiman, Raman, additional, Boorla, Veda Sheersh, additional, Kher, Kartik, additional, Lin, Yi-Chih, additional, Maranas, Costas, additional, Aksimentiev, Aleksei, additional, D. Freeman, Benny, additional, and Kumar, Manish, additional

Published
2024
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26. Wave attenuation properties of rubble mound breakwater in tandem with a floating dock against oblique regular waves.

Author

Khan, Mohamin B.M., Gayathri, R., and Behera, Harekrushna

Subjects
BOUNDARY element methods, BREAKWATERS, EIGENFUNCTION expansions, SHORE protection, SUBMERGED structures, WATER waves
Abstract

This work examines the impact of oblique wave action on a combination of a rubble mound breakwater and a floating dock. The influence of the breakwater on safety of the floating dock is examined in various configurations. The breakwater is approximated by a submerged trapezoidal structure and the floating dock by a surface piercing rigid rectangular structure. A numerical solution is developed combining the eigenfunction expansion method and the multi-domain boundary element method while assuming linear water wave theory. Reflection and transmission coefficients along with wave forces on the dock are evaluated and analyzed over a wide parameter range. The study reveals that the sloping angle of the trapezoidal breakwater plays a vital role in dissipating the wave load on the floating dock and the case of a trapezoidal breakwater with a vertical lee side faces is also examined. The reflection and transmission of waves are found to be dominated by the floating dock parameters in the system, while the wave forces on the dock are reduced by increasing the length and breadth of the breakwater and frictional coefficient of the porous structure, respectively. The combination of two structures in different tandem configurations is proposed as an effective coastal protection system. [ABSTRACT FROM AUTHOR]

Published
2024
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43. Journal of Membrane Science / Biophysical quantification of unitary solute and solvent permeabilities to enable translation to membrane science

Author

Wachlmayr, Johann, Samineni, Laxmicharan, Knyazev, Denis G., Barta, Thomas, Speletz, Armin, Yao, Chenhao, Oh, Hyeonji, Behera, Harekrushna, Ren, Tingwei, Kumar, Manish, and Horner, Andreas

Subjects
Biomimetic membranes, Biophysical techniques, Molecular transport characterization, Membrane proteins, Artificial channels
Abstract

Understanding the determinants of permeability and selectivity in biological channels serves two general purposes. It provides fundamental biophysical insights and allows the evaluation of new membrane proteins and artificial channel designs for the development of biomimetic separation membranes. This understanding relies on accurate ways to quantify unitary (single channel) solute and solvent permeabilities. However, the current research in biomimetic and bioinspired membranes and in protein biophysics tends to focus on relative permeabilities. Further, many methods and approximations currently used result in erroneous permeability values which hinder and complicate the comparison between channels. Combined, these gaps in the available measurements obscure the biophysical insights and impede the development of novel high-performance channels. In this review, we summarize in vitro model membrane systems useful to functionally characterize artificial as well as biological channels. We also critically discuss biophysical techniques capable of extracting permeability values and membrane channel densities, which are fundamental parameters required to determine accurate unitary permeability values. Pertinent examples are provided, along with advantages, disadvantages, and potential improvements needed for specific techniques to acquire accurate unitary permeability values for a diverse set of small molecules, including water, ions, weak acids and bases, neutral molecules, and protons. Version of record

Published
2023
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46. Hybrid boundary element and eigenfunction expansion method for wave trapping by a floating porous box near a rigid wall.

Author

Sahoo, Haripriya, Gayathri, R., Khan, Mohamin B. M., and Behera, Harekrushna

Subjects
EIGENFUNCTION expansions, SEA-walls, BOUNDARY element methods, BOUNDARY value problems, WATER waves, REFLECTANCE
Abstract

The interaction between oblique waves and a surface-piercing floating porous box located near to an impermeable sea wall is studied under the hypothesis of linearised water wave theory. The solution for the associated boundary value problem is developed using combined eigenfunction expansion and multi-domain boundary element methods. The reflection coefficients, surface elevation and hydrodynamic loads on the system are computed to examine the effect of different waves and structural parameters. The study reveals that waves reflected by the structure and wall decrease for increasing the porosity of the structure. The normalised spacing from permeable box to the sea wall plays a major role in the attenuation of wave load on the impermeable sea wall. Furthermore, the wave reflection follows a periodically oscillatory trend as the spacing from the box to the wall increases. The study concluded that on the inshore side, a serene environment can be formed in the presence of the floating permeable box. [ABSTRACT FROM AUTHOR]

Published
2023
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49. Scalable Pillar[5]arene-Integrated Poly(arylate-amide) Molecular Sieve Membranes to Separate Light Gases

Author

Song, Woochul, primary, Park, Jaesung, additional, Dasgupta, Subhadeep, additional, Yao, Chenhao, additional, Maroli, Nikhil, additional, Behera, Harekrushna, additional, Yin, Xinyang, additional, Acharya, Durga P., additional, Zhang, Xueyi, additional, Doherty, Cara M., additional, Maiti, Prabal K., additional, Freeman, Benny D., additional, and Kumar, Manish, additional

Published
2022
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