Accurate solution method for the Maxey–Riley equation, and the effects of Basset history

Prasath, S. Ganga; Vasan, Vishal; Govindarajan, Rama

doi:10.1017/jfm.2019.194

Cited by 34 publications

(28 citation statements)

References 31 publications

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“…This is a rather surprising result, since the orderof-magnitude of the B-B term is really small. This t −1/2 decay of the sedimenting velocity has been also recently reported 17 . Further consequences of the B-B term on the motion of particles at low Reynolds numbers may be search for in future investigations.…”

Section: Dynamics With Boussinesq-basset Memorysupporting

confidence: 84%

Drops in the wind: their dispersion and COVID-19 implications

Sandoval,

Vergara

2021

Preprint

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Most of the works on the dispersion of droplets and their COVID-19 (Coronavirus disease) implications address droplets' dynamics in quiescent environments. As most droplets in a common situation are immersed in external flows (such as ambient flows), we consider the effect of canonical flow profiles namely, shear flow, Poiseuille flow, and unsteady shear flow on the transport of spherical droplets of radius ranging from 5µm to 100 µm, which are characteristic lengths in human talking, coughing or sneezing processes. The dynamics we employ satisfies the Maxey-Riley (M-R) equation. An order-of-magnitude estimate allows us to solve the M-R equation to leading order analytically, and to higher order (accounting for the Boussinesq-Basset memory term) numerically. Discarding evaporation, our results to leading order indicate that the maximum travelled distance for small droplets (5µm radius) under a shear/Poiseuille external flow with a maximum flow speed of 1m/s may easily reach more than 250 meters, since those droplets remain in the air for around 600 seconds. The maximum travelled distance was also calculated to leading and higher orders, and it is observed that there is a small difference between the leading and higher order results, and that it depends on the strength of the flow. For example, this difference for droplets of radius 5µm in a shear flow, and with a maximum wind speed of 5m/s, is seen to be around 2m. In general, higher order terms are observed to slightly enhance droplets' dispersion and their flying time. I. INTRODUCTIONSo far, COVID pandemic is still growing, as of 18:34pm Central European Time (CET), February 6 2021, there have been 104, 956, 439 corroborated cases of COVID-19, encompassing 2, 290, 488 deaths, reported to the World Health Organization (WHO). It is believed that airborne transmission is one of the main mechanisms for COVID spreading 1,2 and that potential sources of infected droplets are breathing, sneezing, coughing or simply talking. Unfortunately, most of the reported literature neglects the effect of ambient flows on droplets transport. These flows are often present in daily activities such a wind flows, ventilation generated currents in offices, homes, malls, among other public places.Recent studies suggest that talking may be among the most dangerous mechanisms for generating infected droplets 1,3-5 . According to Tan 5 and Bourouiba 6 , speech induced plumes can travel 1.3m in 2s or even 8m, which is a distance way longer than the 2m social distancing. Abkarian and Stone 3 using high-speed imaging showed that pronouncing consonants (typical to many languages) such as 'Pa','Ba', and 'Ka' are potent aerolization mechanisms. Abkarian et al 4 using theory, experiments, and simulations documented the flow generated after speaking and breathing, which is in fact the responsible for droplets' transport. Notice that the 2m social distancing, only considered quiescent flows 4,6,7 . This situation is not always satisfied in daily conditions, where wind is frequently present either n...

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Section: Dynamics With Boussinesq-basset Memorysupporting

confidence: 84%

Drops in the wind: their dispersion and COVID-19 implications

Sandoval,

Vergara

2021

Preprint

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“…Richardson and Zaki [25] determined the Stokes correction factor to be 1 − .,-, as we will demonstrate, this will serve our purpose to model attenuation effectively. Although the history/Basset force for a single sphere has been investigated by a number of authors, [24,[26][27][28] an expression to account for the concentration dependency of the force is not known and most probably does not exist in the literature. Since the effect of Basset force with respect to that of the Stokes' force or inertial force is smaller, one can safely use the isolated-sphere form of the history force.…”

Section: Modified Hydrodynamicmentioning

confidence: 99%

Ultrasonic propagation in concentrated colloidal dispersions: improvements in a hydrodynamic model

Alam

2020

Journal of Dispersion Science and Technology

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Recent theoretical and experimental findings demonstrate that modeling ultrasonic attenuation of a concentrated colloidal suspension requires inclusion of shear-induced contributions, an element being unaccounted for by most scattering models. Herein, we extend a hydrodynamic model from low to high particle volume fraction by effectively relating the single particle dynamic drag to particle concentration to account for hydrodynamic inter-particle interactions. We calculate an expression for the complex-valued effective dynamic mass density at high concentrations, which is then combined with a viscosity-corrected effective bulk modulus to estimate ultrasonic velocity and attenuation for a monodisperse suspension of solid spherical particles in a viscous liquid. The effective velocity and attenuation are functions of particle volume fraction, frequency, and physical properties of particles and liquid. We compare our results with those from two recently developed scattering models: a multi-modal multiple scattering model and a core-shell effective medium model, each taking into account the viscosity of the host fluid through shear wave influences. Finally, we find that our extended model predicts experimental attenuation data the best for a silica in water suspension compared to the results of other models.

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“…As a first illustration of the power of this approach, Prasath et al (2019) show how particle motion in spatially homogeneous (but still unsteady) flows can be analytically deduced. They derive a formula for q(0, t) which is explicit up to the evaluation of an integral involving the forcing function f (q(0, t), t).…”

Section: Solving the Inertial Particle Equation With Memorymentioning

confidence: 99%

“…For spatially dependent velocity fields, closed-form solutions are generally not available from this approach. An exception is particle migration in planar Couette flow, for which Prasath et al (2019) still derive a new, explicit solution, exploiting the linearity of the velocity in the spatial variable. This solution may serve as an important benchmark for testing numerical schemes for more general, spatially dependent solutions.…”

Section: Solving the Inertial Particle Equation With Memorymentioning

confidence: 99%

“…As many-particle simulations in various media are increasingly popular, the fresh approach of Prasath et al (2019) will undoubtedly generate further activity in this field. As they have already demonstrated, their reformulation yields new closed-form solutions, provides rigorous asymptotic estimates for the particle velocities and inspires new numerical methods.…”

Section: Futurementioning

confidence: 99%

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Solving the inertial particle equation with memory

Haller¹

2019

J. Fluid Mech.

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The dynamics of spherical particles in a fluid flow is governed by the well-accepted Maxey–Riley equation. This equation of motion simply represents Newton’s second law, equating the rate of change of the linear momentum with all forces acting on the particle. One of these forces, the Basset–Boussinesq memory term, however, is notoriously difficult to handle, which prompts most studies to ignore this term despite ample numerical and experimental evidence of its significance. This practice may well change now due to a clever reformulation of the particle equation of motion by Prasath, Vasan & Govindarajan (J. Fluid Mech., vol. 868, 2019, pp. 428–460), who convert the Maxey–Riley equation into a one-dimensional heat equation with non-trivial boundary conditions. Remarkably, this reformulation confirms earlier estimates on particle asymptotics, yields previously unknown analytic solutions and leads to an efficient numerical scheme for more complex flow fields.

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Accurate solution method for the Maxey–Riley equation, and the effects of Basset history

Cited by 34 publications

References 31 publications

Drops in the wind: their dispersion and COVID-19 implications

Drops in the wind: their dispersion and COVID-19 implications

Ultrasonic propagation in concentrated colloidal dispersions: improvements in a hydrodynamic model

Solving the inertial particle equation with memory

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