Search

Your search keyword '"Atwood number"' showing total 403 results
Start Over Descriptor "Atwood number" Publication Year Range Last 50 years
403 results on '"Atwood number"'

1. High-fidelity simulations of Richtmyer–Meshkov flows triggered by a forward-pentagonal bubble with different Atwood numbers.

Author

Singh, Satyvir and Alsaeed, Salman Saud

Subjects
*DIMENSIONLESS numbers, *FLUID dynamics, *ORDINARY differential equations, *FLOW simulations, *GAS flow
Abstract

In fluid dynamics, the Atwood number is a dimensionless parameter that quantifies the density difference between two fluids. It is calculated as A t = (ρ 1 − ρ 2) / (ρ 1 + ρ 2) , where ρ 1 and ρ 2 represent the densities of the respective fluids. This research employs high-fidelity numerical simulations to examine the Atwood number impacts on Richtmyer–Meshkov (RM) flows triggered by a shocked forward-pentagonal bubble. Five distinct gases — SF 6 , Kr, Ar, Ne, and He — are considered within the forward-pentagonal bubble, encompassed by N 2 gas. In these simulations, a third-order discontinuous Galerkin approach is applied to solve a two-dimensional set of compressible Navier–Stokes-Fourier (NSF) equations for two-component gas flows. To discretize space, hierarchical modal basis functions based on orthogonal-scaled Legendre polynomials are employed. This approach simplifies the NSF equations into a set of ordinary differential equations over time, which are solved using an explicit third-order SSP Runge–Kutta algorithm. The numerical results highlight the notable impact of the Atwood number on the evolution of RM flows in the shocked forward-pentagonal bubble, a phenomenon not previously reported in the literature. The Atwood number exerts a significant influence on the flow patterns, leading to intricate wave formations, shock focusing, jet generation, and interface distortion. Moreover, a comprehensive analysis of the these impact elucidates the mechanisms driving vorticity formation during the interaction process. Additionally, the study conducts a thorough quantitative examination of the Atwood number impacts on the flow fields based on integral quantities and interface features. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

2. Stability analysis of water-alumina nanofluid film at the spherical interface.

Author

Agarwal, Shivam, Awasthi, Mukesh Kumar, and Shukla, Atul Kumar

Abstract

The interface of a viscous fluid and A l 2 O 3 -water nanofluid is analyzed through linear instability analysis in a spherical configuration. The viscous fluid lies inside the sphere while the outside region contains nanofluid. In this model, the viscosity of the nanofluid is considered a function of the base fluid viscosity, nanoparticles volume fraction, fractal aggregates, and nanoparticles shape. The perturbed flow is taken as irrotational, and the linear perturbation equations are solved through viscous irrotational theory. The perturbations growth rate can be computed through a 2-degree polynomial and the coefficients of this polynomial are the functions of the Atwood number, Richardson number, Weber number, Reynolds number, etc. The nanofluid interface is found more stable than the viscous fluid interface. The density of nanofluids raises the amplitude of disturbances while the nanofluid's viscosity has a reverse effect. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

3. Insight on the Flow Physics of Shock-driven Elliptical Gas Inhomogeneity with Different Atwood Numbers

Author

Satyvir Singh, Bidesh Sengupta, Mukesh Kumar Awasthi, and Vinesh Kumar

Subjects
shock wave, elliptical bubble, atwood number, vorticity generation., Technology, Mathematics, QA1-939
Abstract

This article investigates the effects of Atwood numbers on the flow physics of shock-driven elliptical gas inhomogeneity based on numerical simulations. We examine five different gases—He, Ne, Ar, Kr, and SF6—that are filled inside an elliptical bubble and surrounded by N2 in order to study flow physics. A high-order modal discontinuous Galerkin finite element approach is used to solve compressible Euler equations for all numerical simulations. In terms of validation studies, the numerical outcomes match the existing experimental data quite well. The findings show that the Atwood number has a significant impact on the characteristics of flow, including wave patterns, the development of vortices, the generation of vorticity, and bubble deformation. When the value of At is greater than zero i.e. At > 0, there is a notable divergence between the incident wave outside the bubble and the transmitted shock wave inside the bubble. Complex wave patterns, including reflected and newly transmitted shock, are seen during the encounter. Interestingly, the transmitted shock and incident shock waves move with the same rates at At ≈ 0. While, compared to the incident shock wave, the transmitted shock wave moves more quickly for At < 0. The influence of Atwood number is then investigated in depth by looking at the vorticity production at the elliptical interface. Furthermore, in the analysis of vorticity production processes, the important spatial integrated domains of average vorticity, dilatational and baroclinic vorticity production terms, and evolution of enstrophy are extended. Finally, a quantitative research based on the interface qualities delves deeply into the influence of the Atwood number on the flow mechanics.

Published
2024
Full Text
View/download PDF

4. Insight on the Flow Physics of Shock-driven Elliptical Gas Inhomogeneity with Different Atwood Numbers.

Author

Singh, Satyvir, Sengupta, Bidesh, Awasthi, Mukesh Kumar, and Kumar, Vinesh

Subjects
EULER equations, SHOCK waves, PHYSICS, VORTEX motion, MANUFACTURING processes
Abstract

This article investigates the effects of Atwood numbers on the flow physics of shock-driven elliptical gas inhomogeneity based on numerical simulations. We examine five different gases--He, Ne, Ar, Kr, and SF6--that are filled inside an elliptical bubble and surrounded by N2 in order to study flow physics. A high-order modal discontinuous Galerkin finite element approach is used to solve compressible Euler equations for all numerical simulations. In terms of validation studies, the numerical outcomes match the existing experimental data quite well. The findings show that the Atwood number has a significant impact on the characteristics of flow, including wave patterns, the development of vortices, the generation of vorticity, and bubble deformation. When the value of At is greater than zero i.e. At > 0, there is a notable divergence between the incident wave outside the bubble and the transmitted shock wave inside the bubble. Complex wave patterns, including reflected and newly transmitted shock, are seen during the encounter. Interestingly, the transmitted shock and incident shock waves move with the same rates at At = 0. While, compared to the incident shock wave, the transmitted shock wave moves more quickly for At < 0. The influence of Atwood number is then investigated in depth by looking at the vorticity production at the elliptical interface. Furthermore, in the analysis of vorticity production processes, the important spatial integrated domains of average vorticity, dilatational and baroclinic vorticity production terms, and evolution of enstrophy are extended. Finally, a quantitative research based on the interface qualities delves deeply into the influence of the Atwood number on the flow mechanics. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

5. Ablative Rayleigh–Taylor instability driven by time-varying acceleration.

Author

Banerjee, Rahul

Abstract

In this article, the asymptotic nonlinear behavior of the Rayleigh–Taylor hydrodynamic instability driven by time dependent variable accelerations of the form g (1 - e - t T ) and g (1 - e - t T ) (1 + cos μ t) has been reported simultaneously. The nonlinear model based on potential flow theory has been extended to describe the effect of afore mentioned accelerations with vorticity generation inside the bubble. It is seen that the asymptotic growth rate and curvature of the tip of the bubble like interface tends to a finite saturation value and depends on the parameters T and μ . Also, an oscillatory behavior is observed for the acceleration g (1 - e - t T ) (1 + cos μ t) . Such time-dependent accelerations are a representative of the flow conditions in several applications including Inertial Confinement Fusion, type la supernova and several Rayleigh–Taylor experiments. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

6. Development of Rayleigh Taylor Instability at Various Atwood Numbers—A Review

Author

Boral, Ayush, Dutta, Souvik, Kumar, Ankit, Chaubdar, Pooja, Harichandan, A. B., Cavas-Martínez, Francisco, Editorial Board Member, Chaari, Fakher, Series Editor, di Mare, Francesca, Editorial Board Member, Gherardini, Francesco, Series Editor, Haddar, Mohamed, Editorial Board Member, Ivanov, Vitalii, Series Editor, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Revankar, Shripad, editor, Muduli, Kamalakanta, editor, and Sahu, Debjyoti, editor

Published
2023
Full Text
View/download PDF

7. Exploring the Atwood number impact on shock-driven hydrodynamic instability at pentagonal interface using discontinuous Galerkin simulations.

Author

Bansal, Sham, Kumar, Ashok, Saini, Akshay, Negi, Anup Singh, and Singh, Satyvir

Subjects
*FLOW simulations, *SULFUR hexafluoride, *VORTEX motion, *RICHTMYER-Meshkov instability, *GAS flow, *GALERKIN methods, *RAYLEIGH-Taylor instability
Abstract

Investigation of Atwood number impact is crucial for comprehending the flow dynamics of the evolving hydrodynamic instability. In this paper, the Atwood number impacts on the shock-driven hydrodynamic instability at a backward-facing pentagonal interface in its early stages are explored numerically. The shock-driven pentagonal interface has a unique property in which the incident angle of the shock wave is constant along the interface edge. This property provides the ideal environment for the shock-refraction process. To examine the Atwood number impact, we consider five distinct gases, including sulfur hexafluoride, krypton, argon, neon, and helium, which are filled inside the pentagonal interface and surrounded by nitrogen gas. A mixed modal discontinuous Galerkin method is used to solve the two-dimensional Navier–Stokes–Fourier equations for two-component gas flows for numerical simulations. The simulation results illustrate that the Atwood number plays a crucial role in the flow fields of the shocked-pentagonal gas interface, which have not been reported in the literature. The flow fields are greatly impacted by the Atwood number, leading to complex wave patterns, shock focusing, jet formation, interface deformation, and vorticity generation. Further, the Atwood number effects on the flow fields are also thoroughly examined by a quantitative study based on the integral quantities and the interface features. Finally, a quantitative analysis is performed to examine the intrinsic differences between the evolution of the flow fields at the square and pentagonal interfaces. • Atwood number impact on RMI at backward-facing pentagonal interface. • Early stage numerical simulations performed with mixed modal DG method. • Comprehensive analysis of vorticity generation and transport mechanisms. • Detailed discussion on integral diagnostic and interface features are presented. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

8. Investigation on the Effects of Atwood Number on the Combustion Performance of Hydrogen-Oxygen Supersonic Mixing Layer

Author

Liu, Chengcheng, Wang, Zi’ang, Yu, Bin, Zhang, Bin, Liu, Hong, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zhang, Junjie James, Series Editor, Jing, Zhongliang, editor, and Zhan, Xingqun, editor

Published
2021
Full Text
View/download PDF

10. Effect of Atwood number on convergent Richtmyer–Meshkov instability.

Author

Tang, Jinggang, Zhang, Fu, Luo, Xisheng, and Zhai, Zhigang

Abstract

Developments of two-dimensional single-mode light/heavy interfaces driven by convergent shock waves are numerically investigated, focusing on the effect of the Atwood number on the Rayleigh–Taylor stabilization, the compressibility and the nonlinearity. Five different test gases, including CO 2 , Kr, R22, R12 and SF 6 , are considered with air as the ambient gas. It is clarified for the first time that the unperturbed interface begins to decelerate when the shock focuses at the convergence center, and the acceleration during the deceleration phase is proportional to the Atwood number. During the first reshock, the interface moves outwards with a deceleration until it starts moving inwards. When the initial interface is weakly disturbed, a more obvious amplitude reduction is observed for the case with a larger Atwood number before the reshock, which means that the Rayleigh–Taylor stabilization is stronger. To assess the effect of the Atwood number on the compressibility and the nonlinearity, three models, including a linear incompressible model, a nonlinear incompressible model and a linear compressible model, are adopted to predict the amplitude growth before the reshock. The results show that the nonlinearity is weak, and is almost not influenced by the Atwood number before the reshock. The compressibility, however, greatly changes the amplitude growth. As the Atwood number increases, the compressibility plays a less significant role in the amplitude growth because a heavier gas is harder to be compressed. Although a gas with a larger specific heat ratio is also difficult to be compressed, the specific heat ratio plays a minor role to the compressibility relative to the Atwood number. During the reshock, the amplitude grows linearly until the nonlinearity in the cases with large Atwood numbers is strong enough to reduce the amplitude growth rate. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

11. Analytical and numerical investigation of Rayleigh–Taylor instability in nanofluids.

Author

Ahuja, Jyoti and Girotra, Pooja

Abstract

This article is a maiden and naive attempt to formulate, analyse and investigate the Rayleigh–Taylor (RT) instability of two superimposed horizontal layers of nanofluids having different densities. Conservation equations are formulated and linearised by keeping in mind that density of the base fluids as well as nanoparticles is not constant. Linearised perturbed equations are sorted out by using the technique of normal modes and a dispersion relation incorporating the effects of surface tension, Atwood number and volume fraction of nanoparticles is obtained. Stable and unstable modes of RT instability are scrutinised using Routh–Hurtwitz criterion in the presence/absence of nanoparticles and presented graphically. Numerical calculations have been performed to explore the effect of surface tension, Atwood number and volume fraction of the nanoparticles. It is observed that in the presence/absence of nanoparticles, surface tension has a significant impact on stabilising the unstable mode of RT instability whereas Atwood number and volume fraction of nanoparticles hasten this instability. The graphical representations of these numerical investigations confirm the very explanation of RT instability under the effect of different parameters that have significant impact on the intensity of growth rate. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

13. Nonlinear Rayleigh–Taylor instability with horizontal magnetic field.

Author

Banerjee, Rahul

Abstract

In this research, the height, curvature and velocity of the bubble tip in Rayleigh–Taylor instability at arbitrary Atwood number with horizontal magnetic field are investigated. To support the earlier simulation and experimental results, the vorticity generation inside the bubble is introduced. It is found that, in early nonlinear stage, the temporal evolution of the bubble tip parameters depends essentially on the strength and initial perturbation of the magnetic field, although the asymptotic nature coincides with the nonmagnetic case. The model proposed here agrees with the previous linear, nonlinear and simulation observations. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

16. Assessing the impact of a novel hemispherical diffuser on a single-tank sensible thermal energy storage system

Author

S. Advaith, Dipti Ranjan Parida, Nikhil Dani, and Saptarshi Basu

Subjects
Jet (fluid), Materials science, Atwood number, Renewable Energy, Sustainability and the Environment, Thermal, Mixing (process engineering), Mechanics, Molten salt, Diffuser (sewage), Coaxial, Thermocline
Abstract

The effects of an inlet inertial jet on the thermal blending of hot and cold heat transfer fluid (molten salt) for a single tank sensible thermal energy storage system are studied using numerical simulations. The simulations show the evolution of the initial stratified layer (thermocline) for a temperature difference of 300 K with a corresponding Atwood number (At) of 0.066. Three diffuser arrangements are investigated: a flat plate solid diffuser, a coaxial ring diffuser with a solid center, and a proposed hemispherical diffuser. The thermal stratifications are examined by a mathematical model named Ideal stratification index (ISI). It is observed that the buoyancy-driven mixing is minimum for the hemispherical diffuser, and the resulting thermocline is 6% better compared to alternative diffusers at 27 l/min. Additionally, the working of the proposed diffuser is demonstrated via experiments with a saline-freshwater combination. These results reveal that the single tank thermocline storage performance can be improved for higher charging/discharging rates using hemispherical diffusers.

Published
2022

19. Linear analysis of Atwood number effects on shear instability in the elastic–plastic solids

Author

Xi Wang, Hao Pan, Xiao-Mian Hu, Sheng-Tao Wang, and Jianwei Yin

Subjects
Physics, Multidisciplinary, Science, Equations of motion, Perfect fluid, Mechanics, Conservative vector field, Article, Momentum, Physics::Fluid Dynamics, Amplitude, Surfaces, interfaces and thin films, Atwood number, Fluid dynamics, Compressibility, Medicine, Growth rate
Abstract

The evolution of shear instability between elastic–plastic solid and ideal fluid which is concerned in oblique impact is studied by developing an approximate linear theoretical model. With the velocities expressed by the velocity potentials from the incompressible and irrotational continuity equations and the pressures obtained by integrating momentum equations with arbitrary densities, the motion equations of the interface amplitude are deduced by considering the continuity of normal velocities and the force equilibrium with the perfectly elastic–plastic properties of solid at interface. The completely analytical formulas of the growth rate and the amplitude evolution are achieved by solving the motion equations. Consistent results are performed by the model and 2D Lagrange simulations. The characteristics of the amplitude development and Atwood number effects on the growth are discussed. The growth of the amplitude is suppressed by elastic–plastic properties of solids in purely elastic stage or after elastic–plastic transition, and the amplitude oscillates if the interface is stable. The system varies from stable to unstable state as Atwood number decreasing. For large Atwood number, elastic–plastic properties play a dominant role on the interface evolution which may influence the formation of the wavy morphology of the interface while metallic plates are suffering obliquely impact.

Published
2021

20. A numerical study of Rayleigh-Taylor instability for various Atwood numbers using ISPH method.

Author

Rahmat, Amin, Tofighi, Nima, and Yildiz, Mehmet

Subjects
COMPUTATIONAL fluid dynamics, IMMISCIBILITY, RAYLEIGH-Taylor instability, HYDRODYNAMICS
Abstract

In this paper, the wall bounded single-mode Rayleigh-Taylor instability (RTI) for a two-phase immiscible fluid system in a confined domain is investigated numerically for various Atwood numbers ranging from At = 0.2 to At = 0.8. Governing equations are discretised using the smoothed particle hydrodynamics (SPH) method. A robust numerical scheme is used to simulate the RTI phenomenon and in order to model the fluid-flow in the vicinity of the interface, transport parameters such as density and viscosity are smoothed using colour function. The surface tension force is coupled to the momentum equation using continuum surface force (CSF) model. It is shown that in general the RTI evolves in three distinct stages, namely linear stability, mushroom-head formation and long-term evolution. The growth rate in the first stage, i.e. the linear instability, shows good agreement with the analytical solution in the literature. The qualitative and quantitative results of second and third stages are introduced and relevant discussions are made. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

23. Reconstruction by Awe's Two‐Fluid Model of Developed Mixing Instabilities

Author

Llor, Antoine, Beig, R., editor, Beiglböck, W., editor, Domcke, W., editor, Englert, B.-G., editor, Frisch, U., editor, Hänggi, P., editor, Hasinger, G., editor, Hepp, K., editor, Hillebrandt, W., editor, Imboden, D., editor, Jaffe, R. L., editor, Lipowsky, R., editor, Löhneysen, H. v., editor, Ojima, I., editor, Sornette, D., editor, Theisen, S., editor, Weise, W., editor, Wess, J., editor, Zittartz, J., editor, and Llor, Antoine

Published
2005
Full Text
View/download PDF

24. Some Perspectives on Further Developments of Models1

Author

Llor, Antoine, Beig, R., editor, Beiglböck, W., editor, Domcke, W., editor, Englert, B.-G., editor, Frisch, U., editor, Hänggi, P., editor, Hasinger, G., editor, Hepp, K., editor, Hillebrandt, W., editor, Imboden, D., editor, Jaffe, R. L., editor, Lipowsky, R., editor, Löhneysen, H. v., editor, Ojima, I., editor, Sornette, D., editor, Theisen, S., editor, Weise, W., editor, Wess, J., editor, Zittartz, J., editor, and Llor, Antoine

Published
2005
Full Text
View/download PDF

25. Review of Different Instability Types and Regimes

Author

Llor, Antoine, Beig, R., editor, Beiglböck, W., editor, Domcke, W., editor, Englert, B.-G., editor, Frisch, U., editor, Hänggi, P., editor, Hasinger, G., editor, Hepp, K., editor, Hillebrandt, W., editor, Imboden, D., editor, Jaffe, R. L., editor, Lipowsky, R., editor, Löhneysen, H. v., editor, Ojima, I., editor, Sornette, D., editor, Theisen, S., editor, Weise, W., editor, Wess, J., editor, Zittartz, J., editor, and Llor, Antoine

Published
2005
Full Text
View/download PDF

26. Comparison of Single and Two‐Fluid Approaches

Author

Llor, Antoine, Beig, R., editor, Beiglböck, W., editor, Domcke, W., editor, Englert, B.-G., editor, Frisch, U., editor, Hänggi, P., editor, Hasinger, G., editor, Hepp, K., editor, Hillebrandt, W., editor, Imboden, D., editor, Jaffe, R. L., editor, Lipowsky, R., editor, Löhneysen, H. v., editor, Ojima, I., editor, Sornette, D., editor, Theisen, S., editor, Weise, W., editor, Wess, J., editor, Zittartz, J., editor, and Llor, Antoine

Published
2005
Full Text
View/download PDF

28. Wall-Resolved Large Eddy Simulations of the Transient Turbulent Fluid Mixing in a Closed System Replicating a Pressurized Thermal Shock

Author

Pierre-Emmanuel Angeli, CEA, Université Paris-Saclay (CEA), Service de Thermo-hydraulique et de Mécanique des Fluides (STMF), Département de Modélisation des Systèmes et Structures (DM2S), CEA-Direction des Energies (ex-Direction de l'Energie Nucléaire) (CEA-DES (ex-DEN)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-CEA-Direction des Energies (ex-Direction de l'Energie Nucléaire) (CEA-DES (ex-DEN)), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay

Subjects
General Chemical Engineering, Flow (psychology), General Physics and Astronomy, 02 engineering and technology, Large Eddy Simulation, 01 natural sciences, Turbulent mixing, 010305 fluids & plasmas, Physics::Fluid Dynamics, Pressurized thermal shock, [SPI]Engineering Sciences [physics], 0203 mechanical engineering, Atwood number, Phase (matter), 0103 physical sciences, Physical and Theoretical Chemistry, Mixing (physics), Physics, Physical model, Turbulence, Variable density, Mechanics, Boussinesq approximation (buoyancy), Boussinesq approximation, 020303 mechanical engineering & transports, TrioCFD, Working fluid
Abstract

International audience; The isothermal mixing of a heavy and a light liquid of different physical properties is numerically investigated by means of Large Eddy Simulations. The validation is based on experimental data held in a system reproducing various components of a pressurized water nuclear reactor, during a scenario of cold water injection at a low Atwood number of 0.05. The flow has two distinct stages: first a buoyancy-driven phase is characterized by a fluid front development in the cold leg and gives rise to Kelvin-Helmholtz whorls under the action of density changes. Then, the heavy liquid discharges into the downcomer filled with light liquid, which causes a turbulent mixing. These phenomena are analyzed through a single-phase approach where the density of the working fluid is either variable or modeled by the Boussinesq approximation. The influence of grid refinement is deeply examined, which shows that the mesh convergence is well achieved for the main flow quantities, unlike the low-magnitude spanwise components. Overall, the numerical solutions are found to reproduce the experimental measurements with a fair accuracy for both physical models used. These latter exhibit similar trends, due to the small density difference under consideration. The predictions in the downcomer appear to be more challenging owing to a strongest turbulence than in the cold leg, some flow features being not properly captured. However, the experimental data in the downcomer are found to be incomplete and somewhat dubious for a strict validation of the numerical simulations. Lastly, the flow distribution in the dowcomer is investigated, providing further insight on the mixing process.

Published
2021

29. The Effect of Liquid Tamping Media on the Growth of Richtmyer–Meshkov Instability in Copper

Author

Joseph Olles, Christopher F. Tilger, Matthew Hudspeth, and Tracy Vogler

Subjects
Physics::Fluid Dynamics, Viscosity, Materials science, Atwood number, Mechanics of Materials, Richtmyer–Meshkov instability, Materials Science (miscellaneous), Solid mechanics, Mechanics, Dissipation, Material properties, Instability, Shock (mechanics)
Abstract

The Richtmyer–Meshkov instability (RMI) arises at an impulsively accelerated interface between two materials of different density. Historically, this instability was studied in fluids. Recently, RMI studies have been extended to investigate material properties of solids. Material strength at high strain-rates in solids have been extracted from the amplitude and growth of the RMI spike in an untamped environment, specifically, the metal-vacuum interface. This technique has also been shown to elucidate material properties in a distended tamping media, metal-porous solid interface. Here, a bridge to understanding the nonlinear mechanical behavior of copper into a liquid tamping media is investigated experimentally and computationally. We show the RMI growth rate and resulting profile are dependent on initial shock strength, as well as the nondimensional perturbation, with an initial Atwood number of $$-0.78$$ . Data collected from a tamped liquid environment range in metal breakout pressures up to ten GPa. This information is used to calibrate and validate numeric model parameters. The oscillatory shock front in the liquid tamping media is used to approximate the viscosity from a transient 1-D analytic approximation. The viscosity is found to be in agreement with other experimental work, however is not determined to be the only dissipative force in the experiment. Hydrocode simulations of our experiments show reasonable alignment with current and previously published work.

Published
2021

31. Experimental investigation on single-medium stratified thermal energy storage system

Author

K.T. Aswathi, Nikhil Dani, S. Advaith, Kamanio Chattopadhyay, Utpal Kumar Chetia, Dipti Ranjan Parida, and Saptarshi Basu

Subjects
Work (thermodynamics), 060102 archaeology, Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Nuclear engineering, 06 humanities and the arts, 02 engineering and technology, Thermal energy storage, Stability (probability), Renewable energy, Atwood number, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0601 history and archaeology, Mean radiant temperature, business, Thermocline, Energy (signal processing)
Abstract

The demand for renewable energy sources is limited by their inherent intermittent nature. The thermal energy storage technique overcomes this shortcoming by allowing storage of naturally occurring energy (e.g. solar) during “non-peak hours”. The article presents an experimental investigation of the sparsely studied ‘single medium thermocline’ (SMT) based single tank sensible thermal energy storage (TES). The work aims to reconsider its potential by minimizing the fluid dynamic perturbations during the charging cycle which disrupt the stability of the thermocline leading to undesirable energy losses. The article discusses the effect of Atwood number (density stratification) and mean temperature on TES effectiveness as well as providing the appropriate thermodynamic insights. Implementation of the experimental procedures and strategies discussed in this article demonstrates a stable thermocline which persists for more than 6 h (hours) with minimal energy degradation.

Published
2021

32. RAYLEIGH-TAYLOR INSTABILITY IN NANOFLUIDS THROUGH POROUS MEDIUM

Author

Jyoti Ahuja and Pooja Girotra

Subjects
Materials science, Mechanical Engineering, Biomedical Engineering, Mechanics, Condensed Matter Physics, Surface tension, Permeability (earth sciences), Nanofluid, Atwood number, Mechanics of Materials, Modeling and Simulation, General Materials Science, Rayleigh–Taylor instability, Porous medium
Published
2021

33. Lattice Boltzmann simulation of the Rayleigh–Taylor Instability (RTI) during the mixing of the immiscible fluids

Author

Adhika Widyaparaga, Deendarlianto, Kumara Ari Yuana, Pranowo, Bahrul Jalaali, Eko Prasetya Budiana, and Indarto

Subjects
Physics, Equation of state, Lattice Boltzmann methods, General Physics and Astronomy, Reynolds number, 02 engineering and technology, Mechanics, 01 natural sciences, Instability, 010305 fluids & plasmas, Physics::Fluid Dynamics, symbols.namesake, Viscosity, 020303 mechanical engineering & transports, 0203 mechanical engineering, Atwood number, 0103 physical sciences, symbols, Rayleigh–Taylor instability, Mathematical Physics, Mixing (physics)
Abstract

The Lattice Boltzmann Method (LBM) was implemented to simulate the two-dimensional (2-D) Rayleigh–Taylor instability (RTI) during the mixing of the immiscible fluids. Two important parameters of the density and the viscosity as represented respectively by the Atwood and the Reynolds numbers were considered. In the calculation the density of two immiscible fluids was calculated by using the equation of state (EOS). In the present simulations, both Atwood and Reynolds numbers were varied in order to investigate the time variations of the interfacial behavior during RTI, the position of bubbles and spikes, and the horizontal average density. The results indicate that the Atwood number has a higher effect than the Reynolds number in the mixing process during RTI. The bubbles and spikes positions go farther in the displacement with the increase of both Reynolds and Atwood numbers. Moreover, the increase of both Reynolds and Atwood numbers accelerate the mixing process during RTI.

Published
2021

35. Temporal instability characteristics of Rayleigh–Taylor and Kelvin–Helmholtz mechanisms of an inviscid cylindrical interface

Author

M. Vadivukkarasan

Subjects
Physics, Jet (fluid), Mechanical Engineering, 02 engineering and technology, Mechanics, Condensed Matter Physics, 01 natural sciences, Instability, Physics::Fluid Dynamics, Surface tension, 020303 mechanical engineering & transports, 0203 mechanical engineering, Atwood number, Mechanics of Materials, Inviscid flow, 0103 physical sciences, Wavenumber, Weber number, 010301 acoustics, Dimensionless quantity
Abstract

The stability characteristics of an inviscid, incompressible and immiscible cylindrical interface are examined using linear temporal theory. The cylindrical interface is subjected to two instability mechanisms, namely Rayleigh–Taylor (R–T) and Kelvin–Helmholtz (K–H) instabilities. The combined action of R–T and K–H in the presence of surface tension is investigated for a hollow jet in an unbounded liquid medium and reported. The problem includes the motion in an axial direction (K–H mechanism) and the radial direction (R–T mechanism) to destabilize the interface. The instability behavior is described by a few operating parameters, namely, Bond number (Bo), Weber number (We) and Atwood number (A). Here, Bond number is attributed to R–T instability whereas Weber number is attributed to K–H instability. The temporal analysis reveals that the Bond number plays a significant role in determining the dominant growth rate, most unstable axial wavenumber and cut-off axial wavenumber. Furthermore, it is also shown through dimensionless energy budget arguments, even a small amount of energy in the radial motion causes the most unstable wavenumber associated with primary atomization to increase significantly.

Published
2020

36. Effect of Atwood number on convergent Richtmyer–Meshkov instability

Author

Xisheng Luo, Zhigang Zhai, Fu Zhang, and Jinggang Tang

Subjects
Physics, Shock wave, Shock (fluid dynamics), Richtmyer–Meshkov instability, Mechanical Engineering, Computational Mechanics, 02 engineering and technology, Mechanics, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, Amplitude, 020401 chemical engineering, Atwood number, 0103 physical sciences, Compressibility, Heat capacity ratio, Growth rate, 0204 chemical engineering
Abstract

Developments of two-dimensional single-mode light/heavy interfaces driven by convergent shock waves are numerically investigated, focusing on the effect of the Atwood number on the Rayleigh–Taylor stabilization, the compressibility and the nonlinearity. Five different test gases, including $$\hbox {CO}_2$$ , Kr, R22, R12 and $$\hbox {SF}_6$$ , are considered with air as the ambient gas. It is clarified for the first time that the unperturbed interface begins to decelerate when the shock focuses at the convergence center, and the acceleration during the deceleration phase is proportional to the Atwood number. During the first reshock, the interface moves outwards with a deceleration until it starts moving inwards. When the initial interface is weakly disturbed, a more obvious amplitude reduction is observed for the case with a larger Atwood number before the reshock, which means that the Rayleigh–Taylor stabilization is stronger. To assess the effect of the Atwood number on the compressibility and the nonlinearity, three models, including a linear incompressible model, a nonlinear incompressible model and a linear compressible model, are adopted to predict the amplitude growth before the reshock. The results show that the nonlinearity is weak, and is almost not influenced by the Atwood number before the reshock. The compressibility, however, greatly changes the amplitude growth. As the Atwood number increases, the compressibility plays a less significant role in the amplitude growth because a heavier gas is harder to be compressed. Although a gas with a larger specific heat ratio is also difficult to be compressed, the specific heat ratio plays a minor role to the compressibility relative to the Atwood number. During the reshock, the amplitude grows linearly until the nonlinearity in the cases with large Atwood numbers is strong enough to reduce the amplitude growth rate.

Published
2020

37. Fundamental study on chaotic transition of two-phase flow regime and free surface instability in gas deaeration process

Author

Sourabh Mukhopadhyay and Nimbalkar Ganesh Pu

Subjects
Physics::Fluid Dynamics, Buoyancy, Materials science, Atwood number, Internal flow, Cavitation, Bubble, Free surface, engineering, Two-phase flow, Mechanics, engineering.material, Volumetric flow rate
Abstract

Deaeration is a process of eliminating aspirated air from liquid in hydraulic reservoirs to avoid cavitation in the downstream pump blades. The complex fluid dynamics associated with deaeration is investigated. The three-dimensional buoyancy driven chaotic behavior of gas-liquid interfacial two-phase flow is studied. Parametric study is executed to understand change in internal flow physics (bubble coalescence, disintegration, horizontal spread, bubble velocity etc.), strength of accelerating Rayleigh-Taylor instability, turbulent kinetic energy, amplitude of upward velocity near free surface, and rise in free surface level with the variation of parameters like incoming mixture flow rate, incoming volume fraction of air, liquid fill depth, and Atwood number. The computations show increment in cavitation, wavenumber and amplitude of upward velocity towards oscillating free surface with incoming flow rate (Re). Cavitation and free surface instability show incremental trend with volume fraction of incoming air forming a kink (cavitation reduces) due to bubble coalescence in a threshold range of volume fraction of incoming air. With the variation of Atwood number, initially cavitation reduces. But after a critical value (A*) of Atwood number, effect of bubble disintegration, and rise of cavitation become prominent, which is formulated with respect to incoming flow rate (Re). With liquid fill depth, cavitation shows a slight decrement with almost equal deaeration and constant wavelength of free surface oscillation at an increasing buoyancy driven upward velocity. Some glimpse of design solution to reduce the cavitation and enhance the deaeration is also studied and formulated to get better understanding.

Published
2020

38. Flow transitions in collisions between vortex-rings and density interfaces

Author

J. Y. Koh, K. W. B. Yeo, J. Long, Tze How New, and School of Mechanical and Aerospace Engineering

Subjects
Collision, Buoyancy, Baroclinity, 02 engineering and technology, engineering.material, Wake, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, symbols.namesake, Atwood number, Condensed Matter::Superconductivity, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Physics, Condensed matter physics, Vortex-Ring, Reynolds number, 020207 software engineering, Vorticity, Condensed Matter Physics, Vortex, Vortex ring, Mechanical engineering [Engineering], symbols, engineering
Abstract

Flow transitions and vortical developments during vortex-ring collisions with a sharp water–oil density interface are studied using planar laser-induced fluorescence and time-resolved particle-image velocimetry techniques. Circular vortex-rings at Reynolds numbers of Re = 1000 , 2000 and 4000 colliding with a density interface characterized by an Atwood number of approximately A= 0.045 were investigated. Results show that at Re = 1000 , collision with the density interface produces vortical structures and flow transitions that are relatively similar to those for a solid-boundary collision. However, the dynamics underlying the present vortical formations and behaviour are different from those associated with solid-boundary collisions, in that the former are driven by baroclinic vorticity generation. Flow behaviour at Re = 2000 shows more significant deformation of the density interface by the vortex-ring but overall behaviour remains comparable. Last but not least, at Re = 4000 , the largest Reynolds number investigated here, the vortex-ring penetrates the density interface almost completely. However, buoyancy effects eventually limit its penetration and reverse its translational direction, such that it crosses back into the oil layer again with its vortex core rotational senses reversed as well. At the same time, vortex-ring fluid is shed and a significant trailing-jet is left in the former’s wake. Nanyang Technological University The authors acknowledge support for the present study by the School of Mechanical & Aerospace Engineering and CN Yang Scholars" Programme at Nanyang Technological University, Singapore. Funding provided for the first author to present this work at the 15th Asian Symposium on Visualization under a School of Mechanical & Aerospace Engineering Enrichment Grant is also gratefully acknowledged.

Published
2020

39. Interaction of a Plane Shock Wave with Regions of Varying Shape and Density in a Finely Divided Gas Suspension

Author

V. A. Davidchuk and D. V. Sadin

Subjects
Shock wave, Materials science, Richtmyer–Meshkov instability, Plane (geometry), General Engineering, Mechanics, Dissipation, Condensed Matter Physics, 01 natural sciences, Instability, 010305 fluids & plasmas, 010101 applied mathematics, Atwood number, 0103 physical sciences, Refraction (sound), 0101 mathematics, Suspension (vehicle), Astrophysics::Galaxy Astrophysics
Abstract

A study has been made of the interaction between a plane shock wave in a gas or a gas suspension and regions of square and rhombiform cross sections differing from the environment in density. A high-stability monotonic scheme with small numerical dissipation was used for calculation. Comparisons with experiments on the refraction of the shock wave on the interface of a binary gas have confirmed the adequacy of the scheme. The influence of the density-ratio factor (Atwood number), the shape of inhomogeneities, and the particle size on the shock wave structure and the development of a Richtmyer–Meshkov instability has been shown.

Published
2020

41. Statistical characteristics of turbulent mixing in spherical and cylindrical converging Richtmyer–Meshkov instabilities

Author

Li Li, Xinliang Li, Changping Yu, and Yaowei Fu

Subjects
Physics, Turbulence, Mechanical Engineering, Reynolds number, Mechanics, Reynolds stress, Condensed Matter Physics, Enstrophy, Physics::Fluid Dynamics, symbols.namesake, Atwood number, Mach number, Mechanics of Materials, Turbulence kinetic energy, symbols, Mixing (physics)
Abstract

In this paper, the Richtmyer–Meshkov instabilities in spherical and cylindrical converging geometries with a Mach number of approximately 1.5 are investigated by using the high resolution implicit large eddy simulation method, and the influence of the geometric effect on the turbulent mixing is investigated. The heavy fluid is sulphur hexafluoride (SF6), and the light fluid is nitrogen (N2). The shock wave converges from the heavy fluid into the light fluid. The Atwood number is 0.678. The total structured and uniform Cartesian grid node number in the main computational domain is 20483. In addition, to avoid the influence of boundary reflection, a sufficiently long sponge layer with 50 non-uniform coarse grids is added for each non-periodic boundary. Present numerical simulations have high and nonlinear initial perturbation levels, which rapidly lead to turbulent mixing in the mixing layers. Firstly, some physical-variable mean profiles, including mass fraction, Taylor Reynolds number, turbulent kinetic energy, enstrophy and helicity, are provided. Second, the mixing characteristics in the spherical and cylindrical turbulent mixing layers are investigated, such as molecular mixing fraction, efficiency Atwood number, turbulent mass-flux velocity and density self-correlation. Then, Reynolds stress and anisotropy are also investigated. Finally, the radial velocity, velocity divergence and enstrophy in the spherical and cylindrical turbulent mixing layers are studied using the method of conditional statistical analysis. Present numerical results show that the geometric effect has a great influence on the converging Richtmyer–Meshkov instability mixing layers.

Published
2021

45. Richtmyer–Meshkov instability of an unperturbed interface subjected to a diffracted convergent shock

Author

Ravi Samtaney, Mahamad Al-Marouf, Juchun Ding, Liyong Zou, Xisheng Luo, and Wan Cheng

Subjects
Physics, Shock wave, Richtmyer–Meshkov instability, Mechanical Engineering, Perturbation (astronomy), Mechanics, Linear stage, Condensed Matter Physics, 01 natural sciences, Instability, 010305 fluids & plasmas, Amplitude, Atwood number, Mechanics of Materials, 0103 physical sciences, Cylinder, 010306 general physics
Abstract

The Richtmyer–Meshkov (RM) instability is numerically investigated on an unperturbed interface subjected to a diffracted convergent shock created by diffracting an initially cylindrical shock over a rigid cylinder. Four gas interfaces are considered with Atwood number ranging from $-0.18$ to 0.67. Results indicate that the diffracted convergent shock increases its strength gradually and reduces its amplitude quickly when it propagates towards the convergence centre. After the strike of the diffracted convergent shock, the initially unperturbed interface deforms with a bulge structure at the centre and two interface steps at both sides, which can be ascribed to the non-uniformity of the pressure distribution behind the diffracted convergent shock. With the decrease of Atwood number, the bulge structure becomes more pronounced. Quantitatively, the interface amplitude experiences a fast but short growing stage and then enters a linear stage. A good collapse of the dimensionless amplitude is found for all cases, which indicates a weak dependence of the growth rate on Atwood number in the deformed shock-induced RM instability. Then the impulsive theory is modified by eliminating the Atwood number and considering the geometry convergence, which well predicts the amplitude growth for the deformed shock-induced RM instability. Finally, the underlying mechanism is decoupled into three parts, and it is found that both the impulsive pressure perturbation and the geometry convergence promote the growth of interface perturbation while the continuous pressure perturbation inhibits the growth. As the Atwood number decreases, the impulsive perturbation plays an increasingly important role, which suggests that the impulsive perturbation dominates the deformed shock-induced RM instability at the linear stage.

Published
2019

46. Sensitivity analyses in a buoyancy-driven closed system with high resolution CFD using Boussinesq approximation and variable density models

Author

Elia Merzari, Jonathan K. Lai, and Yassin A. Hassan

Subjects
Fluid Flow and Transfer Processes, Physics, Buoyancy, business.industry, Mechanical Engineering, Schmidt number, 02 engineering and technology, Mechanics, Computational fluid dynamics, engineering.material, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Particle image velocimetry, Atwood number, 0103 physical sciences, engineering, Boussinesq approximation (water waves), business, Reynolds-averaged Navier–Stokes equations, Large eddy simulation
Abstract

The influences of the Schmidt number and fluid models of the Boussinesq approximation and variable density (low-Mach formulation) are investigated using large eddy simulation (LES) where fluid naturally advects between two tanks connected by a pipe. The geometry resembles a reactor-like vessel which comprises of a cold leg-downcomer region. The closed system consists of two miscible fluids with different densities and viscosities separated by a valve. Analysis with Reynolds-Averaged Navier–Stokes (RANS) is used for calculating Taylor length scales to establish minimum grid resolution for LES. Using particle image velocimetry (PIV) data, validation is conducted for four different magnitudes of Schmidt numbers. Evidence indicates that capturing the effects from the highest Schmidt number is essential for properly predicting fluctuations and instabilities in the flow. Although downcomer comparisons with PIV consist of larger errors, they are explained through additional sensitivity analyses involving initial conditions, geometry, and residual energy. Lastly, the influence of larger density differences is demonstrated using simulations with a higher Atwood number, temporally scaled using the fluid front velocity. Recommendations are made regarding future experiments and simulations for design of similar buoyant mixing problems.

Published
2019

47. Study of hydrodynamic instabilities with a multiphase lattice Boltzmann model.

Author

Velasco, Ali Mauricio and Muñoz, José Daniel

Subjects
*HYDRODYNAMICS, *MULTIPHASE flow, *LATTICE Boltzmann methods, *RAYLEIGH-Taylor instability, *HELMHOLTZ equation, *COMPUTER simulation
Abstract

Rayleigh–Taylor and Kelvin–Helmholtz hydrodynamic instabilities are frequent in many natural and industrial processes, but their numerical simulation is not an easy challenge. This work simulates both instabilities by using a lattice Boltzmann model on multiphase fluids at a liquid-vapour interface, instead of multicomponent systems like the oil–water one. The model, proposed by He, Chen and Zhang (1999) [1] was modified to increase the precision by computing the pressure gradients with a higher order, as proposed by McCracken and Abraham (2005) [2] . The resulting model correctly simulates both instabilities by using almost the same parameter set. It also reproduces the relation γ ∝ A between the growing rate γ of the Rayleigh–Taylor instability and the relative density difference between the fluids (known as the Atwood number A ), but including also deviations observed in experiments at low density differences. The results show that the implemented model is a useful tool for the study of hydrodynamic instabilities, drawing a sharp interface and exhibiting numerical stability for moderately high Reynolds numbers. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

48. Analytical and numerical investigation of Rayleigh–Taylor instability in nanofluids

Author

Jyoti Ahuja and Pooja Girotra

Subjects
Materials science, 010308 nuclear & particles physics, General Physics and Astronomy, Mechanics, 01 natural sciences, Instability, 010305 fluids & plasmas, Physics::Fluid Dynamics, Surface tension, Nanofluid, Atwood number, Normal mode, Dispersion relation, 0103 physical sciences, Volume fraction, Rayleigh–Taylor instability
Abstract

This article is a maiden and naive attempt to formulate, analyse and investigate the Rayleigh–Taylor (RT) instability of two superimposed horizontal layers of nanofluids having different densities. Conservation equations are formulated and linearised by keeping in mind that density of the base fluids as well as nanoparticles is not constant. Linearised perturbed equations are sorted out by using the technique of normal modes and a dispersion relation incorporating the effects of surface tension, Atwood number and volume fraction of nanoparticles is obtained. Stable and unstable modes of RT instability are scrutinised using Routh–Hurtwitz criterion in the presence/absence of nanoparticles and presented graphically. Numerical calculations have been performed to explore the effect of surface tension, Atwood number and volume fraction of the nanoparticles. It is observed that in the presence/absence of nanoparticles, surface tension has a significant impact on stabilising the unstable mode of RT instability whereas Atwood number and volume fraction of nanoparticles hasten this instability. The graphical representations of these numerical investigations confirm the very explanation of RT instability under the effect of different parameters that have significant impact on the intensity of growth rate.

Published
2021

49. Alfven number for the Richtmyer-Meshkov instability in magnetized plasmas

Author

Takayoshi Sano

Subjects
Physics, High Energy Astrophysical Phenomena (astro-ph.HE), Field (physics), Shock (fluid dynamics), Richtmyer–Meshkov instability, FOS: Physical sciences, Astronomy and Astrophysics, Instability, Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), symbols.namesake, Atwood number, Space and Planetary Science, Quantum electrodynamics, Computer Science::Multimedia, symbols, Magnetohydrodynamics, Astrophysics - High Energy Astrophysical Phenomena, Lorentz force
Abstract

Magnetohydrodynamical evolution of the Richtmyer-Meshkov instability (RMI) is investigated by two-dimensional MHD simulations. The RMI is suppressed by a strong magnetic field, whereas the RMI amplifies an ambient magnetic field by many orders of magnitude if the seed field is weak. We have found that the suppression and amplification processes can be evaluated continuously along with the amplitude of the Alfv\'en number $R_A$, which is defined as the ratio of the linear growth velocity of the RMI to the Alfv\'en speed at the interface. When the Alfv\'en number is less than unity, the Lorentz force acting on the fluid mitigates the unstable motion of the RMI significantly, and the interface oscillates stably in this limit. If $R_A \gtrsim 1$, on the other hand, the surface modulation increases due to the growth of the RMI. The maximum strength of the magnetic field is enhanced up to by a factor of $R_A$. This critical feature is universal and independent of the initial Mach number of the incident shock, the Atwood number, corrugation amplitude, and even the direction of the initial magnetic field., Comment: 11 pages, 8 figures, 1 table, accepted for publication in ApJ

Published
2021
Full Text
View/download PDF

50. Inertial effects in dusty Rayleigh-Taylor turbulence

Author

Magnani M.[1, Musacchio S.[1], and Boffetta G.[1]

Subjects
Physics, Gravity (chemistry), Turbulence, Mechanical Engineering, media_common.quotation_subject, particle/fluid flow, turbulent mixing, Mechanics, Condensed Matter Physics, Inertia, Symmetry (physics), Physics::Fluid Dynamics, Atwood number, Mechanics of Materials, Compressibility, Particle density, Mixing (physics), media_common
Abstract

We investigate the dynamics of a dilute suspension of small, heavy particles superposed on a reservoir of still, pure fluid. The study is performed by means of numerical simulations of the Saffman model for a dilute particle suspension (Saffman, J. Fluid Mech., vol. 13, issue 1, 1962, pp. 120–128). In the presence of gravity forces, the interface between the two phases is unstable and evolves in a turbulent mixing layer which broadens in time. In the case of negligible particle inertia, the particle-laden phase behaves as a denser fluid, and the dynamics of the system recovers to that of the incompressible Rayleigh–Taylor set-up. Conversely, particles with large inertia affect the evolution of turbulent flow, delaying the development of turbulent mixing and breaking the up–down symmetry within the mixing layer. The inertial dynamics also leads to particle clustering, characterised by regions with higher particle density than the initial uniform density, and by the increase of the local Atwood number.

Published
2021

Catalog

Books, media, physical & digital resources
See catalog results