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198 results on '"Alam, Meheboob"'

1. Revisiting ignited-quenched transition and the non-Newtonian rheology of a sheared dilute gas-solid suspension

Author

Saha, Saikat and Alam, Meheboob

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

The hydrodynamics and rheology of a sheared dilute gas-solid suspension, consisting of inelastic hard-spheres suspended in a gas, are analysed using anisotropic Maxwellian as the single particle distribution function. The closed-form solutions for granular temperature and three invariants of the second-moment tensor are obtained as functions of the Stokes number ($St$), the mean density ($\nu$) and the restitution coefficient ($e$). Multiple states of high and low temperatures are found when the Stokes number is small, thus recovering the "ignited" and "quenched" states, respectively, of Tsao \& Koch (J. Fluid Mech.,1995). The phase diagram is constructed in the three-dimensional ($\nu, St, e$)-space that delineates the regions of ignited and quenched states and their coexistence. Analytical expressions for the particle-phase shear viscosity and the normal stress differences are obtained, along with related scaling relations on the quenched and ignited states. At any $e$, the shear-viscosity undergoes a discontinuous jump with increasing shear rate (i.e.~ discontinuous shear-thickening) at the "quenched-ignited" transition. The first (${\mathcal N}_1$) and second (${\mathcal N}_2$) normal-stress differences also undergo similar first-order transitions: (i) ${\mathcal N}_1$ jumps from large to small positive values and (ii) ${\mathcal N}_2$ from positive to negative values with increasing $St$, with the sign-change of ${\mathcal N}_2$ identified with the system making a transition from the quenched to ignited states. The superior prediction of the present theory over the standard Grad's method and the Chapman-Enskog solution is demonstrated via comparisons of transport coefficients with simulation data for a range of Stokes number and restitution coefficient.

Published
2017
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2. Scale dependence and non-isochoric effects on the thermohydrodynamics of rarefied Poiseuille flow.

Author

Ravichandir, Shashank and Alam, Meheboob

Subjects
POISEUILLE flow, FLUID mechanics, STREAMFLOW velocity, NONEQUILIBRIUM flow, KNUDSEN flow, MASS transfer
Abstract

The article examines the thermohydrodynamics of rarefied Poiseuille flow in a finite length channel, emphasizing the impact of dilatation and non-isochoric effects. Variations in pressure-driven and acceleration-driven Poiseuille flows are discussed, with a focus on the saturation of mass flow rate at high Knudsen numbers in pressure-driven flow. The study highlights the significance of dilatation in explaining differences in hydrodynamic fields, rheology, and flow-induced heat transfer between the two flows, as well as the implementation of boundary conditions and averaging procedures in the DSMC method. The research suggests that further exploration is needed to understand the implications of dilatation in various flow scenarios and discusses the challenges in solving the Boltzmann equation using the DSMC method. [Extracted from the article]

Published
2024
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3. Variable-cell method for stress-controlled jamming of athermal, frictionless grains

Author

Smith, Kyle C., Srivastava, Ishan, Fisher, Timothy S., and Alam, Meheboob

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

A new method is introduced to simulate jamming of polyhedral grains under controlled stress that incorporates global degrees of freedom through the metric tensor of a periodic cell containing grains. Jamming under hydrostatic/isotropic stress and athermal conditions leads to a precise definition of the ideal jamming point at zero shear stress. The structures of tetrahedra jammed hydrostatically exhibit less translational order and lower jamming-point density than previously described `maximally random jammed' hard tetrahedra. Under the same conditions, cubes jam with negligible nematic order. Grains with octahedral symmetry jam in the large-system limit with an abundance of face-face contacts in the absence of nematic order. For sufficiently large face-face contact number, percolating clusters form that span the entire simulation box. The response of hydrostatically jammed tetrahedra and cubes to shear-stress perturbation is also demonstrated with the variable-cell method., Comment: 10 pages, 8 figures

Published
2014
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4. Isostaticity of Constraints in Jammed Systems of Soft Frictionless Platonic Solids

Author

Smith, Kyle C., Alam, Meheboob, and Fisher, Timothy S.

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science, Condensed Matter - Statistical Mechanics
Abstract

The average number of constraints per particle $< C_{total} >$ in mechanically stable systems of Platonic solids (except cubes) approaches the isostatic limit at the jamming point ($< C_{total} > \rightarrow 12$), though average number of contacts are hypostatic. By introducing angular alignment metrics to classify the degree of constraint imposed by each contact, constraints are shown to arise as a direct result of local orientational order reflected in edge-face and face-face alignment angle distributions. With approximately one face-face contact per particle at jamming chain-like face-face clusters with finite extent form in these systems., Comment: 4 pages, 3 figures, 4 table

Published
2011
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5. Athermal jamming of soft frictionless Platonic solids

Author

Smith, Kyle C., Alam, Meheboob, and Fisher, Timothy S.

Subjects
Condensed Matter - Soft Condensed Matter, Mathematical Physics
Abstract

A mechanically-based structural optimization method is utilized to explore the phenomena of jamming for assemblies of frictionless Platonic solids. Systems of these regular convex polyhedra exhibit mechanically stable phases with density substantially less than optimal for a given shape, revealing that thermal motion is necessary to access high density phases. We confirm that the large system jamming threshold of $0.623 \pm 0.003$ for tetrahedra is consistent with experiments on tetrahedral dice. Also, the extremely short-ranged translational correlations of packed tetrahedra observed in experiments are confirmed here, in contrast with those of thermally simulated glasses. Though highly ordered phases are observed to form for small numbers of cubes and dodecahedra, the short correlation length scale suppresses ordering in large systems, resulting in packings that are mechanically consistent with `orientationally disordered' contacts (point-face and edge-edge contacts). Mild nematic ordering is observed for large systems of cubes, whereas angular correlations for the remaining shapes are ultra short-ranged. Power-law scaling exponents for energy with respect to distance from the jamming threshold exhibit a clear dependence on the `highest order' percolating contact topology. These nominal exponents are 6, 4, and 2 for configurations having percolating point-face (or edge-edge), edge-face, and face-face contacts, respectively. These Platonic solids exhibit hypostatic behavior, with average jamming contact number between the isostatic value for spheres and that of asymmetric particles. These shapes violate the isostatic conjecture, displaying contact number that decreases monotonically with sphericity. The common symmetry of dual polyhedra results in local translational structural similarity. (Note abstract abridged due to length constraint), Comment: 49 pages, 13 figures, 2 tables

Published
2010
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6. Universality of shear-banding instability and crystallization in sheared granular fluid

Author

Alam, Meheboob, Shukla, Priyanka, and Luding, Stefan

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

The linear stability analysis of an uniform shear flow of granular materials is revisited using several cases of a Navier-Stokes'-level constitutive model in which we incorporate the global equation of states for pressure and thermal conductivity (which are accurate up-to the maximum packing density $\nu_{m}$) and the shear viscosity is allowed to diverge at a density $\nu_\mu$ ($< \nu_{m}$), with all other transport coefficients diverging at $\nu_{m}$. It is shown that the emergence of shear-banding instabilities (for perturbations having no variation along the streamwise direction), that lead to shear-band formation along the gradient direction, depends crucially on the choice of the constitutive model. In the framework of a dense constitutive model that incorporates only collisional transport mechanism, it is shown that an accurate global equation of state for pressure or a viscosity divergence at a lower density or a stronger viscosity divergence (with other transport coefficients being given by respective Enskog values that diverge at $\nu_m$) can induce shear-banding instabilities, even though the original dense Enskog model is stable to such shear-banding instabilities. For any constitutive model, the onset of this shear-banding instability is tied to a {\it universal} criterion in terms of constitutive relations for viscosity and pressure, and the sheared granular flow evolves toward a state of lower "dynamic" friction, leading to the shear-induced band formation, as it cannot sustain increasing dynamic friction with increasing density to stay in the homogeneous state. A similar criterion of a lower viscosity or a lower viscous-dissipation is responsible for the shear-banding state in many complex fluids., Comment: 26 pages

Published
2008
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7. Linear stability, transient energy growth and the role of viscosity stratification in compressible plane Couette flow

Author

Malik, M., Dey, J., and Alam, Meheboob

Subjects
Physics - Fluid Dynamics
Abstract

Linear stability and the non-modal transient energy growth in compressible plane Couette flow are investigated for two prototype mean flows: (a) the {\it uniform shear} flow with constant viscosity, and (b) the {\it non-uniform shear} flow with {\it stratified} viscosity. Both mean flows are linearly unstable for a range of supersonic Mach numbers ($M$). For a given $M$, the critical Reynolds number ($Re$) is significantly smaller for the uniform shear flow than its non-uniform shear counterpart. An analysis of perturbation energy reveals that the instability is primarily caused by an excess transfer of energy from mean-flow to perturbations. It is shown that the energy-transfer from mean-flow occurs close to the moving top-wall for ``mode I'' instability, whereas it occurs in the bulk of the flow domain for ``mode II''. For the non-modal analysis, it is shown that the maximum amplification of perturbation energy, $G_{\max}$, is significantly larger for the uniform shear case compared to its non-uniform counterpart. For $\alpha=0$, the linear stability operator can be partitioned into ${\cal L}\sim \bar{\cal L} + Re^2{\cal L}_p$, and the $Re$-dependent operator ${\cal L}_p$ is shown to have a negligibly small contribution to perturbation energy which is responsible for the validity of the well-known quadratic-scaling law in uniform shear flow: $G(t/{\it Re}) \sim {\it Re}^2$. A reduced inviscid model has been shown to capture all salient features of transient energy growth of full viscous problem. For both modal and non-modal instability, it is shown that the {\it viscosity-stratification} of the underlying mean flow would lead to a delayed transition in compressible Couette flow.

Published
2008
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8. Nonmodal energy growth and optimal perturbations in compressible plane Couette flow

Author

Malik, M., Alam, Meheboob, and Dey, J.

Subjects
Physics - Fluid Dynamics
Abstract

Nonmodal transient growth studies and estimation of optimal perturbations have been made for the compressible plane Couette flow with three-dimensional disturbances. The maximum amplification of perturbation energy over time, $G_{\max}$, is found to increase with increasing Reynolds number ${\it Re}$, but decreases with increasing Mach number $M$. More specifically, the optimal energy amplification $G_{\rm opt}$ (the supremum of $G_{\max}$ over both the streamwise and spanwise wavenumbers) is maximum in the incompressible limit and decreases monotonically as $M$ increases. The corresponding optimal streamwise wavenumber, $\alpha_{\rm opt}$, is non-zero at M=0, increases with increasing $M$, reaching a maximum for some value of $M$ and then decreases, eventually becoming zero at high Mach numbers. While the pure streamwise vortices are the optimal patterns at high Mach numbers, the modulated streamwise vortices are the optimal patterns for low-to-moderate values of the Mach number. Unlike in incompressible shear flows, the streamwise-independent modes in the present flow do not follow the scaling law $G(t/{\it Re}) \sim {\it Re}^2$, the reasons for which are shown to be tied to the dominance of some terms in the linear stability operator. Based on a detailed nonmodal energy analysis, we show that the transient energy growth occurs due to the transfer of energy from the mean flow to perturbations via an inviscid {\it algebraic} instability. The decrease of transient growth with increasing Mach number is also shown to be tied to the decrease in the energy transferred from the mean flow ($\dot{\mathcal E}_1$) in the same limit.

Published
2008
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9. Orientational correlation and velocity distributions in uniform shear flow of a dilute granular gas

Author

Gayen, Bishakdatta and Alam, Meheboob

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics
Abstract

Using particle simulations of the uniform shear flow of a rough dilute granular gas, we show that the translational and rotational velocities are strongly correlated in direction, but there is no orientational correlation-induced singularity at perfectly smooth ($\beta=-1$) and rough ($\beta=1$) limits for elastic collisions ($e=1$); both the translational and rotational velocity distribution functions remain close to a Gaussian for these two limiting cases. Away from these two limits, the orientational as well as spatial velocity correlations are responsible for the emergence of non-Gaussian high velocity tails. The tails of both distribution functions follow stretched exponentials, with the exponents depending on normal ($e$) and tangential ($\beta$) restitution coefficients., Comment: Physical Review Letters (accepted)

Published
2008
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10. Effects of Prandtl number and a new instability mode in a plane thermal plume

Author

Lakkaraju, R. and Alam, Meheboob

Subjects
Physics - Fluid Dynamics, Physics - Geophysics
Abstract

The effect of Prandtl number on the linear stability of a plane thermal plume is analyzed under quasi-parallel approximation. At large Prandtl numbers ($Pr>100$), we found that there is an additional unstable loop whose size increases with increasing $Pr$. The origin of this new instability mode is shown to be tied to the coupling of the momentum and thermal perturbation equations. Analyses of the perturbation kinetic energy and thermal energy suggest that the buoyancy force is the main source of perturbation energy at high Prandtl numbers that drives this instability.

Published
2008

11. Hydrodynamic Theory for Reverse Brazil Nut Segregation and the Non-monotonic Ascension Dynamics

Author

Alam, Meheboob, Trujillo, Leonardo, and Herrmann, Hans J.

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics
Abstract

Based on the Boltzmann-Enskog kinetic theory, we develop a hydrodynamic theory for the well known (reverse) Brazil nut segregation in a vibro-fluidized granular mixture. Using an analogy with standard fluid mechanics, we have recently suggested a novel mechanism of segregation in granular mixtures based on a {\it competition between buoyancy and geometric forces}: the Archimedean buoyancy force, a pseudo-thermal buoyancy force due to the difference between the energies of two granular species, and two geometric forces, one compressive and the other-one tensile in nature, due to the size-difference. For a mixture of perfectly hard-particles with elastic collisions, the pseudo-thermal buoyancy force is zero but the intruder has to overcome the net compressive geometric force to rise. For this case, the geometric force competes with the standard Archimedean buoyancy force to yield a threshold density-ratio, $R_{\rho 1}=\rho_l/\rho_s < 1$, above which the {\it lighter intruder sinks}, thereby signalling the {\it onset} of the {\it reverse buoyancy} effect. For a mixture of dissipative particles, the non-zero pseudo-thermal buoyancy force gives rise to another threshold density-ratio, $R_{\rho 2}$ ($> R_{\rho 1}$), above which the intruder rises again. Focussing on the {\it tracer} limit of intruders in a dense binary mixture, we find that the rise-time of the intruder could vary {\it non-monotonically} with the density-ratio. For a given size-ratio, there is a threshold density-ratio for the intruder at which it takes the maximum time to rise, and above(/below) which it rises faster, implying that {\it the heavier (and larger) the intruder, the faster it ascends}. Our theory offers a unified description for the (reverse) Brazil-nut segregation and the non-monotonic ascension dynamics of Brazil-nuts.

Published
2008

12. Velocity Distribution and the Effect of Wall Roughness in Granular Poiseuille Flow

Author

Vijayakumar, K. C. and Alam, Meheboob

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics
Abstract

From event-driven simulations of a gravity-driven channel flow of inelastic hard-disks, we show that the velocity distribution function remains close to a Gaussian for a wide range densities (even when the Knudsen number is of order one) if the walls are smooth and the particle collisions are nearly elastic. For dense flows, a transition from a Gaussian to a power-law distribution for the high velocity tails occurs with increasing dissipation in the center of the channel, irrespective of wall-roughness. For a rough wall, the near-wall distribution functions are distinctly different from those in the bulk even in the quasielastic limit.

Published
2008
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13. Hydrodynamics, normal stress differences and heat transfer in rarefied pressure driven Poiseuille flow.

Author

Ravichandir, Shashank and Alam, Meheboob

Subjects
*POISEUILLE flow, *HEAT transfer, *KNUDSEN flow, *HYDRODYNAMICS, *GAS flow, *GRANULAR flow, *NON-Newtonian flow (Fluid dynamics)
Abstract

A parallelized Direct Simulation Monte Carlo (DSMC) solver is developed to solve the Boltzmann equation for the pressure-driven Poiseuille flow of monatomic gases over a range of Knudsen numbers in the slip and transitional regimes. The non-Newtonian and non-Fourier effects, along with hydrodynamic fields and rheology, are investigated and compared to the more widely studied acceleration-driven Poiseuille flow. The slip velocity is extracted from the velocity profiles and is expressed in terms of the Knudsen number as a power law. The non-Newtonian effects on stresses are characterised by defining two normal-stress differences whose variations in the stream-wise and wall-normal directions are studied. In addition, the normal and tangential heat fluxes are calculated from the simulation. To isolate the entrance and exit effects, the simulation is carried out for different aspect ratios of the channel keeping the pressure gradient constant. Finally this study is extended to the pressure-driven flow of rarefied granular gases. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Universal Unfolding of Pitchfork Bifurcations and Shear-Band Formation in Rapid Granular Couette Flow

Author

Alam, Meheboob

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics
Abstract

A numerical bifurcation analysis is carried out to understand the role of gravity on the shear-band formation in rapid granular Couette flow. At {\it low} shear rates, there is a unique solution with a {\it plug} near the bottom wall and a {\it shear-layer} near the top-wall; this solution mirrors typical shearbanding-type profiles in earth-bound shear-cell experiments. Interestingly, a {\it stable} plug near the top-wall is also a solution of these equations at {\it high} shear rates; there is a multitude of other plugged states, with the plugs being located in an ordered fashion within the Couette gap. The origin of such shearbanding solutions is tied to the spontaneous symmetry-breaking {\it shearbanding} instabilities of the gravity-free uniform shear flow, leading to both subcritical and supercritical pitchfork bifurcations. In the language of singularity theory, we have established that this bifurcation problem admits {\it universal unfolding} of pitchfork bifurcations., Comment: 11 pages and 6 figures; Proceedings of the Symposium on Trends in Applications of Mathematics to Mechanics, 22-28 August, 2004, Seeheim-Jugenheim, Germnay (Editors: K. Hutter and Y. Wang)

Published
2004

15. First normal stress difference and crystallization in a dense sheared granular fluid

Author

Alam, Meheboob and Luding, Stefan

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics
Abstract

The first normal stress difference (${\mathcal N}_1$) and the microstructure in a dense sheared granular fluid of smooth inelastic hard-disks are probed using event-driven simulations. While the anisotropy in the second moment of fluctuation velocity, which is a Burnett-order effect, is known to be the progenitor of normal stress differences in {\it dilute} granular fluids, we show here that the collisional anisotropies are responsible for the normal stress behaviour in the {\it dense} limit. As in the elastic hard-sphere fluids, ${\mathcal N}_1$ remains {\it positive} (if the stress is defined in the {\it compressive} sense) for dilute and moderately dense flows, but becomes {\it negative} above a critical density, depending on the restitution coefficient. This sign-reversal of ${\mathcal N}_1$ occurs due to the {\it microstructural} reorganization of the particles, which can be correlated with a preferred value of the {\it average} collision angle $\theta_{av}=\pi/4 \pm \pi/2$ in the direction opposing the shear. We also report on the shear-induced {\it crystal}-formation, signalling the onset of fluid-solid coexistence in dense granular fluids. Different approaches to take into account the normal stress differences are discussed in the framework of the relaxation-type rheological models., Comment: 21 pages, 13 figures

Published
2003
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16. Multiplicity of states in Taylor-Couette flow of a dense granular gas

Author

Gopan Nandu and Alam Meheboob

Subjects
Physics, QC1-999
Abstract

Molecular dynamics simulations with a purely repulsive Lennard-Jones potential and a normal damping force is used to simulate the granular flow in the annular region between two differentially-rotating cylinders, called the Taylor-Couette flow. The flow transition from the azimuthally-invariant Circular Couette flow (CCF) to the Taylor-vortex flow (TVF) is studied by increasing the rotation rate (ωi) of the inner cylinder, with the outer cylinder being kept stationary. Multiplicity of states, highlighting the hysteretic nature of the “CCF ↔ TVF” transition, is observed over a wide range of rotation rates. The onset of Taylor vortices is quantified in terms of the maximum radial velocity and the net circulation per vortex.

Published
2021
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20. Supplementary Material on 'Unified torque scaling in counter-rotating suspension Taylor–Couette flow'

Author

Alam, Meheboob and Ghosh, Manojit

Abstract

Torque measurements are reported for the Taylor–Couette flow of a neutrally buoyant non-colloidal suspension in the counter-rotation regime upto a particle volume fraction of $\phi =0.2$. A unified scaling relation for the dimensionless torque (the pseudo-Nusselt number) of the form $\mbox {\rm Nu}_{\omega 0} = ( \alpha _0 + \alpha _1{\mbox {\rm Ta}_{1}^*}^{\alpha _2}) \mbox {\rm Ta}( 0) ^{k} {\mu _r( \phi ) }^{n}$ is shown to hold over a range of Taylor number $\mbox {\rm Ta}^{c1} \leq \mbox {\rm Ta}\leq ~10^6$ that covers primary, secondary and tertiary bifurcating states; here, $\mbox {\rm Ta}_1^*= \mbox {\rm Ta}( \phi ) /\mbox {\rm Ta}^{c1}( \phi ) $ is the reduced Taylor number, $\mbox {\rm Ta}^{c1}$ is the critical Taylor number at primary bifurcation and $\mu _r( \phi ) =\mu ( \phi ) /\mu ( 0) $ is the relative viscosity of the suspension. Possible effects of flow transitions and inhomogeneous distribution of particles on torque scaling are discussed.This article is part of the theme issue ‘Taylor–Couette and related flows on the centennial of Taylor’s seminal Philosophical Transactions paper (Part 1)’.

Published
2022
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23. Oblique shock waves in granular flows over bluff bodies

Author

Gopan Nandu and Alam Meheboob

Subjects
Physics, QC1-999
Abstract

Granular flows around an object have been the focus of numerous analytical, experimental and simulation studies. The structure and nature of the oblique shock wave developed when a quasi-two dimensional flow of spherical granular particles streams past an immersed, fixed cylindrical obstacle forms the focus of this study. The binary granular mixture, consisting of particles of the same diameter but different material properties, is investigated by using a modified LIGGGHTS package as the simulation engine. Variations in the solid fraction and granular temperature within the resulting flow are studied. The Mach number is calculated and is used to distinguish between the subsonic and the supersonic regions of the bow shock.

Published
2017
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24. Normal stress differences and beyond-Navier-Stokes hydrodynamics

Author

Alam Meheboob and Saha Saikat

Subjects
Physics, QC1-999
Abstract

A recently proposed beyond-Navier-Stokes order hydrodynamic theory for dry granular fluids is revisited by focussing on the behaviour of the stress tensor and the scaling of related transport coefficients in the dense limit. For the homogeneous shear flow, it is shown that the eigen-directions of the second-moment tensor and those of the shear tensor become co-axial, thus making the first normal stress difference (N1) to zero in the same limit. In contrast, the origin of the second normal stress difference (N2) is tied to the ‘excess’ temperature along the mean-vorticity direction and the imposed shear field, respectively, in the dilute and dense flows. The scaling relations for transport coefficients are suggested based on the present theory.

Published
2017
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38. Nonlinear axisymmetric Taylor–Couette flow in a dilute gas: multiroll transition and the role of compressibility.

Author

Aghor, Pratik and Alam, Meheboob

Subjects
AXIAL flow, GAS flow, GAS compressibility, MACH number, COMPRESSIBILITY, TAYLOR vortices, CROSS-flow (Aerodynamics)
Abstract

The compressible Navier–Stokes–Fourier equations are numerically solved for axially bounded Taylor–Couette flow (TCF) of an ideal gas, with rotating inner cylinder and stationary outer cylinder, to understand the roles of compressibility and finite aspect ratio on the genesis of nonlinear Taylor vortices and the related bifurcation scenario. Restricting to the axisymmetric case in the wide-gap limit, the aspect ratio $\varGamma =h/\delta$ (where $\delta$ is the annular gap between two cylinders and $h$ is the height of the cylinders) is changed quasistatically by varying the height of the cylinders, following the experimental protocol of Benjamin (Proc. R. Soc. Lond. A, vol. 359, 1978b, pp. 27–43). The symmetric even-numbered ($2,4,6,\ldots$) vortices are found at $\varGamma \geq 2$ , whereas the asymmetric 2-roll modes (called the single-roll or 'anomalous' modes), that break the midplane $Z_{2}$ -symmetry, are uncovered at $\varGamma \leq O(1)$. The phase boundaries of both symmetric and asymmetric rolls and the coexisting regions of different number of rolls are identified in the ($\varGamma , Re$)-plane. These phase diagrams, along with related bifurcation diagrams and various patterns, at finite Mach numbers ($Ma$) are contrasted with their incompressible ($Ma\to 0$) analogues. It is shown that the ' $1\leftrightarrow 2$ '-roll transition in small aspect ratio cylinders is subcritical in compressible TCF in contrast to the supercritical nature of bifurcation in its incompressible counterpart. In general, the gas compressibility has a stabilizing effect on nonlinear Taylor vortices as the underlying phase diagrams in the ($\varGamma , Re$)-plane are shifted to larger values of $Re$ with increasing $Ma$. The stabilizing role of compressibility can be tied to the weakening of the outward jets, which is further aided by the strengthening of the Ekman vortices with increasing Mach number. [ABSTRACT FROM AUTHOR]

Published
2021
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50. Nonlinear instability and convection in a vertically vibrated granular bed

Author

Shulka, Priyanka, Ansari, Istafaul I.H., Van Der Meer, Devaraj, Lohse, Detlef, Alam, Meheboob, Shulka, Priyanka, Ansari, Istafaul I.H., Van Der Meer, Devaraj, Lohse, Detlef, and Alam, Meheboob

Abstract

The nonlinear instability of the density-inverted granular Leidenfrost state and the resulting convective motion in strongly shaken granular matter are analysed via a weakly nonlinear analysis of the hydrodynamic equations. The base state is assumed to be quasi-steady and the effect of harmonic shaking is incorporated by specifying a constant granular temperature at the vibrating plate. Under these mean-field assumptions, the base-state temperature decreases with increasing height away from the vibrating plate, but the density profile consists of three distinct regions: (i) a collisional dilute layer at the bottom, (ii) a levitated dense layer at some intermediate height and (iii) a ballistic dilute layer at the top of the granular bed. For the nonlinear stability analysis (Shukla & Alam, J. Fluid Mech. vol. 672, 2011b, pp. 147-195), the nonlinearities up to cubic order in the perturbation amplitude are retained, leading to the Landau equation, and the related adjoint stability problem is formulated taking into account appropriate boundary conditions. The first Landau coefficient and the related modal eigenfunctions (the fundamental mode and its adjoint, the second harmonic and the base-flow distortion, and the third harmonic and the cubic-order distortion to the fundamental mode) are calculated using a spectral-based numerical method. The genesis of granular convection is shown to be tied to a supercritical pitchfork bifurcation from the density-inverted Leidenfrost state. Near the bifurcation point the equilibrium amplitude (Ae) is found to follow a square-root scaling law, Ae ∼ Δ, with the distance Δ from the bifurcation point. We show that the strength of convection (measured in terms of velocity circulation) is maximal at some intermediate value of the shaking strength, with weaker convection at both weaker and stronger shaking. Our theory predicts that at very strong shaking the convective motion remains concentrated only near the top sur, SCOPUS: ar.j, info:eu-repo/semantics/published

Published
2014

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