Physical Review Fluids
Grid resolution requirement for resolving rare and high intensity wall-shear stress events in direct numerical simulations
Author(s): Xiang I. A. Yang, Jiarong Hong, Myoungkyu Lee, and Xinyi L. D. Huang
Wall-shear stress becomes more intermittent as the Reynolds number (Re) of a flow increases. To properly resolve wall shear stress events in direct numerical simulations thus requires finer grids at higher Re. In this work we examine the grid resolution required to resolve a given percentage of wall shear stress events as a function of Re. We find that the standard grid resolution does not capture a fraction of high intensity events which increases with Re and quantify the grid resolution needed to do so.
[Phys. Rev. Fluids 6, 054603] Published Fri May 07, 2021
Relation between the spectral properties of wall turbulence and the scaling of the Darcy-Weisbach friction factor
Author(s): Francesco Coscarella, Roberto Gaudio, Gabriel G. Katul, and Costantino Manes
Empirical formulae describing the Darcy-Weisbach friction factor remain indispensable for applications in sciences and engineering dealing with turbulent flows. Despite their practical significance, these formulae have remained without theoretical interpretation for many decades. To close this knowledge gap we provide, using a co-spectral budget model, a clarification of the link between spectral properties of velocity fluctuations and the scaling of friction factors in turbulent pipe flows in the hydraulically smooth and fully rough regimes.
[Phys. Rev. Fluids 6, 054601] Published Thu May 06, 2021
Author(s): Ting Wu and Guowei He
A dynamic autoregressive (DAR) random forcing model is proposed for space-time energy spectra in turbulent shear flows. This model starts with Taylor’s convection model and introduces the DAR random forcing to represent the random sweeping effect. The DAR model is further combined with linear stochastic estimation (LSE) to reconstruct the near-wall velocity fluctuations.
[Phys. Rev. Fluids 6, 054602] Published Thu May 06, 2021
Author(s): I. Gluzman and D. F. Gayme
The input-output approach is expanded to investigate actuated wall-bounded shear flows whose geometries and input signals span a range of pulse-width modulated signals common in experimental flow control studies. The model is validated through comparisons to experiments and simulations of three different plasma actuator geometries. An important benefit of this analytical method is the low computational cost associated with its use, enabling efficient parametric studies.
[Phys. Rev. Fluids 6, 053901] Published Wed May 05, 2021
Vertical distribution and longitudinal dispersion of gyrotactic microorganisms in a horizontal plane Poiseuille flow
Author(s): Bohan Wang, Weiquan Jiang, Guoqian Chen, Luoyi Tao, and Zhi Li
A more concise and accurate generalized Taylor dispersion theory is applied to dispersion of active gyrotactic microorganisms in a plane Poiseuille flow. The joint effect of boundary conditions, cell shape anisotropy, swimming speed, and flow speed leads to the nonmonotonic variations of the phenomenological dispersion coefficients.
[Phys. Rev. Fluids 6, 054502] Published Wed May 05, 2021
Author(s): H. Hassanzadeh, A. Eslami, and S. M. Taghavi
Using a high-speed camera, laser imaging and ultrasound velocimetry, we study positively buoyant miscible jets. Based on the appearance of the laminar length, we classify the flow into fully turbulent and semi-turbulent regimes. We quantify the regime transition boundaries and propose empirical correlations to predict the laminar length. To have a global view of the flow, we also analyze the quasi-steady jet characteristics (jet radius, spread angle, virtual origin, velocity profiles and energy dissipation) and starting jet characteristics (penetration length and tip velocity).
[Phys. Rev. Fluids 6, 054501] Published Tue May 04, 2021
Author(s): David Gross, Yann Roux, Christophe Raufaste, and Argentina Médéric
Fish swim by undulating their body to ensure propulsion. In a steady state, thrust is balanced by the total drag force, for which the dominant terms depend on the Reynolds number and the flow regime. In this article we propose a set of simple scaling laws to determine the contribution of each mechanism to the drag exerted on the swimmer.
[Phys. Rev. Fluids 6, 053101] Published Mon May 03, 2021
Author(s): Alex Skvortsov, Timothy C. DuBois, Milan Jamriska, and Martin Kocan
Since the seminal results of Batchelor, Morton and Turner who laid the foundations of classical convective plume theory, it has been recognized that convective thermals exhibit remarkable scaling properties. In this paper, the authors identify dynamics of strong thermals which can be drastically different from weak Boussinesq-type thermals. In general, the evolution of thermals is affected by the interplay of two processes: entrainment flux caused by thermal expansion and solid-body acceleration of the thermal centroid. As a result, depending on the density contrast between the thermal and the ambient environment, scaling laws are modified with different power-law exponents.
[Phys. Rev. Fluids 6, 053501] Published Mon May 03, 2021
Erratum: Material transport in the left ventricle with aortic valve regurgitation [Phys. Rev. Fluids <b>3</b>, 113101 (2018)]
Author(s): Giuseppe Di Labbio, Jérôme Vétel, and Lyes Kadem
[Phys. Rev. Fluids 6, 059901] Published Mon May 03, 2021
Author(s): Samya Sen, Anthony G. Morales, and Randy H. Ewoldt
We report the first-ever experimental study of thixotropic aging in viscoplastic drop impact. A new dimensionless group is proposed and validated. The results will be useful in predicting splash behavior in a variety of applications from spray coating to fire suppression.
[Phys. Rev. Fluids 6, 043301] Published Fri Apr 30, 2021
Author(s): Grégoire Martouzet, Loren Jørgensen, Yoann Pelet, Anne-Laure Biance, and Catherine Barentin
We study the spreading of drops made of yield-stress fluids. In contrast to what is observed in Newtonian fluids, the final contact angle reached by the drop depends on the drop size, on its yield stress, and on the liquid/solid hydrodynamic boundary condition. This highlights the crucial role of dynamic history. We then extend the classical Young’s law to the case of yield stress fluids. In particular, by considering that the final shape of the drop is set by a dynamical arrest, we predict the observed final contact angle.
[Phys. Rev. Fluids 6, 044006] Published Fri Apr 30, 2021
Author(s): Yuan Wang, Zheng Chen, and Haitao Chen
Two-dimensional simulations considering detailed chemistry are conducted to investigate the weakly unstable detonation diffracting through an obstacle. Subcritical, critical, and supercritical regimes are identified and their distributions are significantly affected by the obstacle size and shape. In contrast, the mixtures with different nitrogen dilution have little influence on the regime distributions.
[Phys. Rev. Fluids 6, 043201] Published Thu Apr 29, 2021
Author(s): Shuolin Xiao, Chen Peng, and Di Yang
Bubble-driven plume in stratified crossflow is modeled using Eulerian-Eulerian large-eddy simulation. Various bubble sizes and crossflow velocities are considered, and noticeable differences in the plume characteristics and material transport are observed. Statistical analysis of the simulation results provides insights on how the crossflow affects the exchanges of momentum and mass between the bubble-driven plume and the surrounding water.
[Phys. Rev. Fluids 6, 044613] Published Thu Apr 29, 2021
Author(s): Utkarsh Jain, Anaïs Gauthier, Detlef Lohse, and Devaraj van der Meer
A solid plate about to slam onto a water surface makes it presence felt before the actual contact by squeezing out a mediating air cushioning layer. This air cushioning layer has regions of low and high pressures. At the point of high (stagnation) air pressure, the water surface is deflected away from the impactor. While in the low pressure region, a Kelvin-Helmholtz instability initiates the suction of the water surface towards the impactor. Using a new measuring technique we measure such deflections, of the order of 10-300 microns, and explain the mechanisms driving them.
[Phys. Rev. Fluids 6, L042001] Published Thu Apr 29, 2021
Author(s): Thijs de Goede, Karla de Bruin, Noushine Shahidzadeh, and Daniel Bonn
Drop splashing on surfaces is important for a wide variety of processes ranging from inkjet printing to pollination by rain and forensic blood pattern analysis. The critical impact velocity beyond which the drop disintegrates is well understood for smooth surfaces, but remained a puzzle for rougher ones that are often encountered in practice. We find that the splashing threshold on rough surfaces is lower, which can be understood as an interplay between the surface roughness and the viscous, inertial, and capillary forces on the drop.
[Phys. Rev. Fluids 6, 043604] Published Wed Apr 28, 2021
Author(s): Hamid Tabaei Kazerooni, Georgy Zinchenko, Jörg Schumacher, and Christian Cierpka
A tiny electrical voltage can be generated by the collective coupling of the electron spins to the flow vorticity in laminar and turbulent liquid metal flows. Here, we demonstrate a linear scaling law between electrical voltage and pressure drop for laminar flows through capillaries with different cross sections, both, analytically and experimentally.
[Phys. Rev. Fluids 6, 043703] Published Wed Apr 28, 2021
Author(s): S. Mawet, H. Caps, and S. Dorbolo
Soap bubbles are easy to deform: a child blowing, the wind, or an electric field imposed by a plane capacitor are some possible examples. When an electric field is applied, a bubble elongates along the direction of the field, deforming into a spheroid. For a sufficiently high electric field, bubbles eventually become conical, forming a so-called Taylor cone. In addition to the dependence on the electric field and the soapy solution used, the shape of a bubble is also related to the substrate on which it rests, namely a solid plate or a liquid bath.
[Phys. Rev. Fluids 6, 043603] Published Tue Apr 27, 2021
Coupled x-ray high-speed imaging and pressure measurements in a cavitating backward facing step flow
Author(s): G. Maurice, N. Machicoane, S. Barre, and H. Djeridi
The two-phase flow generated behind a cavitating backward-facing step is studied using the combination of three experimental techniques: wall-pressure measurements, global high-speed imaging with visible light, and high spatial and temporal resolution x-ray imaging. Three zones are identified based on the topology of the vapor fraction maps, that correspond to vaporization, transport, and condensation. Simultaneous pressure and void fraction measurements reveal that extreme events are associated with a change from a shear layer mode to a wake mode, with a temporal signature that is heavily affected by the presence of the vapor phase.
[Phys. Rev. Fluids 6, 044311] Published Tue Apr 27, 2021
Author(s): Veronica Angeles, Francisco A. Godínez, Jhonny A. Puente-Velazquez, Rodrigo Mendez-Rojano, Eric Lauga, and Roberto Zenit
We conduct experiments to study magnetic helical swimmers in viscoelastic fluids. The swimming speed is strongly influenced by the tail-to-head size ratio: the speed can be larger, similar, or smaller than the Newtonian one depending on the value of the size ratio. We conjecture that this size asymmetry induces a net viscoelastic force that affects the swimming speed.
[Phys. Rev. Fluids 6, 043102] Published Mon Apr 26, 2021
Author(s): Jens Eggers
Like the bubble tip frozen into a drinking glass, very sharp tips are formed generically at the end of drops and bubbles in strong flows. We show that the tip curvature is exponentially large in the square of the flow strength, and that the bubble ends are almost conical, but with a slope that increases logarithmically as the tip is approached. This solution of the viscous flow equations is shown to match to the slender bubble shape valid away from the tip, found by G.I. Taylor.
[Phys. Rev. Fluids 6, 044005] Published Mon Apr 26, 2021