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734 results on '"Lohse, D."'

1. Kinematics and dynamics of freely rising spheroids at high Reynolds numbers

Author

Will, J. B., Mathai, V., Huisman, S. G., Lohse, D., Sun, C., and Krug, D.

Subjects
Physics - Fluid Dynamics
Abstract

We experimentally investigate the effect of geometrical anisotropy for buoyant ellipsoidal particles rising in a still fluid. All other parameters, such as the Galileo number $Ga \approx 6000$ and the particle density ratio $\Gamma \approx 0.53$ are kept constant. The geometrical aspect ratio, $\chi$, of the particle is varied systematically from $\chi$ = 0.2 (oblate) to 5 (prolate). Based on tracking all degrees of particle motion, we identify six regimes characterised by distinct rise dynamics. Firstly, for $0.83 \le \chi \le 1.20$, increased rotational dynamics are observed and the particle flips over semi-regularly in a "tumbling"-like motion. Secondly, for oblate particles with $0.29 \le \chi \le 0.75$, planar regular "zig-zag" motion is observed, where the drag coefficient is independent of $\chi$. Thirdly, for the most extreme oblate geometries ($\chi \le 0.25$) a "flutter"-like behaviour is found, characterised by precession of the oscillation plane and an increase in the drag coefficient. For prolate geometries, we observed two coexisting oscillation modes that contribute to complex trajectories: the first is related to oscillations of the pointing vector and the second corresponds to a motion perpendicular to the particle's symmetry axis. We identify a "longitudinal" regime ($1.33 \le \chi \le 2.5$), where both modes are active and a different one, the "broadside"-regime ($3 \le \chi\le 4$), where only the second mode is present. Remarkably, for the most prolate particles ($\chi = 5$), we observe an entirely different "helical" rise with completely unique features., Comment: 46 pages, 20 figures

Published
2020
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2. Caf\'e Latte: Spontaneous layer formation in laterally cooled double diffusive convection

Author

Chong, K. L., Yang, R., Wang, Q., Verzicco, R., and Lohse, D.

Subjects
Physics - Fluid Dynamics, Physics - Geophysics
Abstract

In the preparation of Caf\'e Latte, spectacular layer formation can occur between the expresso shot in a glass of milk and the milk itself. Xue et al. (Nat. Commun., vol. 8, 2017, pp. 1-6) showed that the injection velocity of expresso determines the depth of coffee-milk mixture. After a while when a stable stratification forms in the mixture, the layering process can be modelled as a double diffusive convection system with a stably-stratified coffee-milk mixture cooled from the side. More specifically, we perform (two-dimensional) direct numerical simulations of laterally cooled double diffusive convection for a wide parameter range, where the convective flow is driven by a lateral temperature gradient while stabilized by a vertical concentration gradient. When the thermal driving force dominates over the stabilizing force, the flow behaves like vertical convection in which a large-scale circulation develops. However, with increasing strength of the stabilizing force, a meta-stable layered regime emerges. Initially, several vertically-stacked convection rolls develop, and these well-mixed layers are separated by sharp interfaces with large concentration gradients. The initial thickness of these emerging layers can be estimated by balancing the work exerted by thermal driving and the required potential energy to bring fluid out of its equilibrium position in the stably stratified fluid. In the layered regime, we further observe successive layer merging, and eventually only a single convection roll remains. We elucidate the following merging mechanism: As weakened circulation leads to accumulation of hot fluid adjacent to the hot sidewall, larger buoyancy forces associated with hotter fluid eventually break the layer interface. Then two layers merge into a larger layer, and circulation establishes again within the merged structure., Comment: 10 pages, 4 figures

Published
2020
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3. Pathways to electrochemical solar-hydrogen technologies

Author

Ardo, S, Fernandez Rivas, D, Modestino, MA, Schulze Greiving, V, Abdi, FF, Alarcon Llado, E, Artero, V, Ayers, K, Battaglia, C, Becker, JP, Bederak, D, Berger, A, Buda, F, Chinello, E, Dam, B, Di Palma, V, Edvinsson, T, Fujii, K, Gardeniers, H, Geerlings, H, Hashemi, SM, Haussener, S, Houle, F, Huskens, J, James, BD, Konrad, K, Kudo, A, Kunturu, PP, Lohse, D, Mei, B, Miller, EL, Moore, GF, Muller, J, Orchard, KL, Rosser, TE, Saadi, FH, Schüttauf, JW, Seger, B, Sheehan, SW, Smith, WA, Spurgeon, J, Tang, MH, Van De Krol, R, Vesborg, PCK, and Westerik, P

Subjects
Bioengineering, MD Multidisciplinary, Energy
Abstract

Solar-powered electrochemical production of hydrogen through water electrolysis is an active and important research endeavor. However, technologies and roadmaps for implementation of this process do not exist. In this perspective paper, we describe potential pathways for solar-hydrogen technologies into the marketplace in the form of photoelectrochemical or photovoltaic-driven electrolysis devices and systems. We detail technical approaches for device and system architectures, economic drivers, societal perceptions, political impacts, technological challenges, and research opportunities. Implementation scenarios are broken down into short-term and long-term markets, and a specific technology roadmap is defined. In the short term, the only plausible economical option will be photovoltaic-driven electrolysis systems for niche applications. In the long term, electrochemical solar-hydrogen technologies could be deployed more broadly in energy markets but will require advances in the technology, significant cost reductions, and/or policy changes. Ultimately, a transition to a society that significantly relies on solar-hydrogen technologies will benefit from continued creativity and influence from the scientific community.

Published
2018

5. Inside a kettle

Author

Wildeman, S., Lhuissier, H., Sun, C., and Lohse, D.

Subjects
Physics - Fluid Dynamics
Abstract

This fluid dynamics video images the different heat transport mechanisms at play when a liquid confined in a vertical Hele-Shaw cell is heated from below. The two-dimensional time resolved temperature field inside the cell is measured by a quantitative Schlieren technique which is detailed in the video., Comment: Includes high res and low res version of video for the APS-DFD gallery of fluid motion 2012 #83753

Published
2012

6. Diffusive shielding stabilizes bulk nanobubble clusters

Author

Weijs, Joost H., Seddon, James R. T., and Lohse, D.

Subjects
Physics - Fluid Dynamics
Abstract

Using molecular dynamics, we study the nucleation and stability of bulk nanobubble clusters. We study the formation, growth, and final size of bulk nanobubbles. We find that, as long as the bubble-bubble interspacing is small enough, bulk nanobubbles are stable against dissolution. Simple diffusion calculations provide an excellent match with the simulation results, giving insight into the reason for the stability: nanobubbles in a cluster of bulk nanobubbles "protect" each other from diffusion by a shielding effect.

Published
2011
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7. Formation of surface nanobubbles and universality of their contact angles: A molecular dynamics approach

Author

Weijs, J. H., Snoeijer, J. H., and Lohse, D.

Subjects
Physics - Fluid Dynamics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study surface nanobubbles using molecular dynamics simulation of ternary (gas, liquid, solid) systems of Lennard-Jones fluids. They form for sufficiently low gas solubility in the liquid, i.e., for large relative gas concentration. For strong enough gas-solid attraction, the surface nanobubble is sitting on a gas layer, which forms in between the liquid and the solid. This gas layer is the reason for the universality of the contact angle, which we calculate from the microscopic parameters. Under the present equilibrium conditions the nanobubbles dissolve within less of a microsecond, consistent with the view that the experimentally found nanobubbles are stabilized by a nonequilibrium mechanism., Comment: 5p,4f

Published
2011
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8. On bubble clustering and energy spectra in pseudo-turbulence

Author

Martinez, J., Chehata, D., van Gils, D. P. M., Sun, C., and Lohse, D.

Subjects
Physics - Fluid Dynamics
Abstract

3D-Particle Tracking (3D-PTV) and Phase Sensitive Constant Temperature Anemometry in pseudo-turbulence--i.e., flow solely driven by rising bubbles-- were performed to investigate bubble clustering and to obtain the mean bubble rise velocity, distributions of bubble velocities, and energy spectra at dilute gas concentrations ($\alpha \leq2.2$%). To characterize the clustering the pair correlation function $G(r,\theta)$ was calculated. The deformable bubbles with equivalent bubble diameter $d_b=4-5$ mm were found to cluster within a radial distance of a few bubble radii with a preferred vertical orientation. This vertical alignment was present at both small and large scales. For small distances also some horizontal clustering was found. The large number of data-points and the non intrusiveness of PTV allowed to obtain well-converged Probability Density Functions (PDFs) of the bubble velocity. The PDFs had a non-Gaussian form for all velocity components and intermittency effects could be observed. The energy spectrum of the liquid velocity fluctuations decayed with a power law of -3.2, different from the $\approx -5/3$ found for homogeneous isotropic turbulence, but close to the prediction -3 by \cite{lance} for pseudo-turbulence.

Published
2009
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9. Acceleration of heavy and light particles in turbulence: comparison between experiments and direct numerical simulations

Author

Volk, R., Calzavarini, E., Verhille, G., Lohse, D., Mordant, N., Pinton, J. -F., and Toschi, F.

Subjects
Nonlinear Sciences - Chaotic Dynamics, Physics - Fluid Dynamics
Abstract

We compare experimental data and numerical simulations for the dynamics of inertial particles with finite density in turbulence. In the experiment, bubbles and solid particles are optically tracked in a turbulent flow of water using an Extended Laser Doppler Velocimetry technique. The probability density functions (PDF) of particle accelerations and their auto-correlation in time are computed. Numerical results are obtained from a direct numerical simulation in which a suspension of passive pointwise particles is tracked, with the same finite density and the same response time as in the experiment. We observe a good agreement for both the variance of acceleration and the autocorrelation timescale of the dynamics; small discrepancies on the shape of the acceleration PDF are observed. We discuss the effects induced by the finite size of the particles, not taken into account in the present numerical simulations., Comment: 7 pages, 4 figures

Published
2007
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10. Dynamics of the spontaneous breakdown of superhydrophobicity

Author

Pirat, C., Sbragaglia, M., Peters, A. M., Borkent, B. M., Lammertink, R. G. H., Wessling, M., and Lohse, D.

Subjects
Physics - Fluid Dynamics, Condensed Matter - Disordered Systems and Neural Networks, Nonlinear Sciences - Pattern Formation and Solitons
Abstract

Drops deposited on rough and hydrophobic surfaces can stay suspended with gas pockets underneath the liquid, then showing very low hydrodynamic resistance. When this superhydrophobic state breaks down, the subsequent wetting process can show different dynamical properties. A suitable choice of the geometry can make the wetting front propagate in a stepwise manner leading to {\it square-shaped} wetted area: the front propagation is slow and the patterned surface fills by rows through a {\it zipping} mechanism. The multiple time scale scenario of this wetting process is experimentally characterized and compared to numerical simulations., Comment: 7 pages, 5 figures

Published
2007
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11. Exponentially growing solutions in homogeneous Rayleigh-Benard convection

Author

Calzavarini, E., Doering, C. R., Gibbon, J. D., Lohse, D., Tanabe, A., and Toschi, F.

Subjects
Nonlinear Sciences - Chaotic Dynamics
Abstract

It is shown that homogeneous Rayleigh-Benard flow, i.e., Rayleigh-Benard turbulence with periodic boundary conditions in all directions and a volume forcing of the temperature field by a mean gradient, has a family of exact, exponentially growing, separable solutions of the full non-linear system of equations. These solutions are clearly manifest in numerical simulations above a computable critical value of the Rayleigh number. In our numerical simulations they are subject to secondary numerical noise and resolution dependent instabilities that limit their growth to produce statistically steady turbulent transport., Comment: 4 pages, 3 figures, to be published in Phys. Rev. E - rapid communications

Published
2006
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12. Wind reversals in turbulent Rayleigh-Benard convection

Author

Araujo, Francisco Fontenele, Grossmann, S., and Lohse, D.

Subjects
Nonlinear Sciences - Chaotic Dynamics
Abstract

The phenomenon of irregular cessation and subsequent reversal of the large-scale circulation in turbulent Rayleigh-B\'enard convection is theoretically analysed. The force and thermal balance on a single plume detached from the thermal boundary layer yields a set of coupled nonlinear equations, whose dynamics is related to the Lorenz equations. For Prandtl and Rayleigh numbers in the range $10^{-2} \leq \Pr \leq 10^{3}$ and $10^{7} \leq \Ra \leq 10^{12}$, the model has the following features: (i) chaotic reversals may be exhibited at Ra $\geq 10^{7}$; (ii) the Reynolds number based on the root mean square velocity scales as $\Re_{rms} \sim \Ra^{[0.41 ... 0.47]}$ (depending on Pr), and as $\Re_{rms} \sim \Pr^{-[0.66 ... 0.76]}$ (depending on Ra); and (iii) the mean reversal frequency follows an effective scaling law $\omega / (\nu L^{-2}) \sim \Pr^{-(0.64 \pm 0.01)} \Ra^{0.44 \pm 0.01}$. The phase diagram of the model is sketched, and the observed transitions are discussed., Comment: 4 pages, 5 figures

Published
2004
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13. Response maxima in modulated turbulence Part II: Numerical simulations

Author

von der Heydt, A., Grossmann, S., and Lohse, D.

Subjects
Nonlinear Sciences - Chaotic Dynamics
Abstract

Numerical simulations of fully developed turbulence driven by a modulated energy input rate or driving force are performed within two dynamical cascade models, the GOY shell model and a reduced wave vector set approximation of the Navier-Stokes equation (REWA). The frequency behavior of the system response is studied and compared with predictions from a variable range mean-field theory, which excludes turbulent fluctuations. In agreement with the mean-field approach we find a constant response amplitude for low driving frequencies and a 1/w-decay of the amplitude for high frequencies. In the mean-field theory, the finite cascade time scale had lead to an oscillating behavior of the response amplitude as a function of the driving frequency. In the simulations of both models we observe the main maximum. The higher maxima and minima are completely washed out by fluctuations., Comment: 12 pages, 10 figures, submitted to Phys.Rev. E

Published
2003
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14. Response maxima in modulated turbulence

Author

von der Heydt, A., Grossmann, S., and Lohse, D.

Subjects
Nonlinear Sciences - Chaotic Dynamics
Abstract

Isotropic and homogeneous turbulence driven by an energy input modulated in time is studied within a variable range mean-field theory. The response of the system, observed in the second order moment of the large-scale velocity difference D(L,t)=<<(\u(x+L)-\u(x))^2>>~Re(t)^2$, is calculated for varying modulation frequencies w and weak modulation amplitudes. For low frequencies the system follows the modulation of the driving with almost constant amplitude, whereas for higher driving frequencies the amplitude of the response decreases on average 1/w. In addition, at certain frequencies the amplitude of the response either almost vanishes or is strongly enhanced. These frequencies are connected with the frequency scale of the energy cascade and multiples thereof., Comment: 11 pages, 6 figures

Published
2003
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15. Transitions and Probes in Turbulent Helium

Author

Emsellem, V., Kadanoff, L., Lohse, D., Tabeling, P., and Wang, J.

Subjects
Nonlinear Sciences - Chaotic Dynamics
Abstract

Previous analysis of a Paris turbulence experiment \cite{zoc94,tab95} shows a transition at the Taylor Reynolds number $\rel \approx 700$. Here correlation function data is analyzed which gives further evidence for this transition. It is seen in both the power spectrum and in structure function measurements. Two possible explanations may be offered for this observed transition: that it is intrinsic to the turbulence flow in this closed box experiment or that it is an effect of a change in the flow around the anemometer. We particularly examine a pair of ``probe effects''. The first is a thermal boundary layer which does exist about the probe and does limit the probe response, particularly at high frequencies. Arguments based on simulations of the response and upon observations of dissipation suggests that this effect is only crucial beyond $\rel\approx 2000$. The second effect is produced by vortex shedding behind the probe. This has been seen to produce a large modification in some of the power spectra for large $\rel$. It might also complicate the interpretation of the experimental results. However, there seems to be a remaining range of data for $\rel < 1300$ uncomplicated by these effects, and which are thus suggestive of an intrinsic transition., Comment: uuencoded .ps files. submitted to PRE. 12 figures are sent upon request to jane wang (jw@control.uchicago.edu)

Published
1996
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18. Homogeneous Rayleigh-Bénard Convection

Author

Calzavarini, E., Lohse, D., Toschi, F., Oberlack, Martin, editor, Khujadze, George, editor, Günther, Silke, editor, Weller, Tanja, editor, Frewer, Michael, editor, Peinke, Joachim, editor, and Barth, Stephan, editor

Published
2007
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21. Strong alignment of prolate ellipsoids in Taylor-Couette flow

Author

Assen, MPA, Ng, CS, Will, JB, Stevens, RJAM, Lohse, D, Verzicco, R, Assen, MPA, Ng, CS, Will, JB, Stevens, RJAM, Lohse, D, and Verzicco, R

Abstract

We report on the mobility and orientation of finite-size, neutrally buoyant, prolate ellipsoids (of aspect ratio $\varLambda =4$ ) in Taylor–Couette flow, using interface-resolved numerical simulations. The set-up consists of a particle-laden flow between a rotating inner and a stationary outer cylinder. The flow regimes explored are the well-known Taylor vortex, wavy vortex and turbulent Taylor vortex flow regimes. We simulate two particle sizes $\ell /d=0.1$ and $\ell /d=0.2$ , $\ell$ denoting the particle major axis and $d$ the gap width between the cylinders. The volume fractions are $0.01\,\%$ and $0.07\,\%$ , respectively. The particles, which are initially randomly positioned, ultimately display characteristic spatial distributions which can be categorised into four modes. Modes (i) to (iii) are observed in the Taylor vortex flow regime, while mode (iv) encompasses both the wavy vortex and turbulent Taylor vortex flow regimes. Mode (i) corresponds to stable orbits away from the vortex cores. Remarkably, in a narrow $\textit {Ta}$ range, particles get trapped in the Taylor vortex cores (mode (ii)). Mode (iii) is the transition when both modes (i) and (ii) are observed. For mode (iv), particles distribute throughout the domain due to flow instabilities. All four modes show characteristic orientational statistics. The focus of the present study is on mode (ii). We find the particle clustering for this mode to be size-dependent, with two main observations. Firstly, particle agglomeration at the core is much higher for $\ell /d=0.2$ compared with $\ell /d=0.1$ . Secondly, the $\textit {Ta}$ range for which clustering is observed depends on the particle size. For this mode (ii) we observe particles to align strongly with the local cylinder tangent. The most pronounced particle alignment is observed for $\ell /d=0.2$ at around $\textit {Ta}=4.2\times 10^5$ . This observation is found to closely correspond to a minimum of axial vorticity at the Taylor vortex core ( $

Published
2022

29. Coriolis effect on centrifugal buoyancy-driven convection in a thin cylindrical shell

Author

Rouhi, A, Lohse, D, Marusic, I, Sun, C, Chung, D, Rouhi, A, Lohse, D, Marusic, I, Sun, C, and Chung, D

Abstract

We study the effect of the Coriolis force on centrifugal buoyancy-driven convection in a rotating cylindrical shell with inner cold wall and outer hot wall. This is done by performing direct numerical simulations for increasing inverse Rossby number Ro−1 from zero (no Coriolis force) to 20 (very large Coriolis force) and for Rayleigh number Ra from 107 to 1010 and Prandtl number Pr=0.7, corresponding to air. We invoke the thin-shell limit, which neglects the curvature and radial variations of the centripetal acceleration. As Ro−1 increases from zero, the system forms an azimuthal bidirectional wind that reaches its maximum momentum at an optimal Ro−1opt, associated with a maximal skin-friction coefficient Cf and a minimal Nusselt number Nu. Just beyond Ro−1opt, the wind weakens and an axial, quasi-two-dimensional cyclone, corotating with the system, begins to form. A local ‘turbulence’ inverse Rossby number (non-dimensionalised by the eddy turnover time) determines the onset of cyclone formation for all Ra, when its value reaches approximately 4. At Ro−1≫Ro−1opt, the system falls into the geostrophic regime with a sudden drop in Nu. The bidirectional wind for Ro−1≤Ro−1opt is a feature of this system, as it hastens the boundary layer transition from laminar to turbulent, towards the ultimate regime. We see the onset of this transition at Ra=1010 and Ro−1≃Ro−1opt, although the mean flow profile has not yet fully collapsed on the Prandtl–von Kármán (logarithmic) law.

Published
2021

30. Characterizing the turbulent drag properties of rough surfaces with a Taylor-Couette set-up

Author

Berghout, P, Bullee, PA, Fuchs, T, Scharnowski, S, Kaehler, CJ, Chung, D, Lohse, D, Huisman, SG, Berghout, P, Bullee, PA, Fuchs, T, Scharnowski, S, Kaehler, CJ, Chung, D, Lohse, D, and Huisman, SG

Abstract

Wall roughness induces extra drag in wall-bounded turbulent flows. Mapping any given roughness geometry to its fluid dynamic behaviour has been hampered by the lack of accurate and direct measurements of skin-friction drag. Here, the Taylor–Couette (TC) system provides an opportunity as it is a closed system and allows direct and reliable measurement of the skin-friction. However, the wall curvature potentially complicates the connection between the wall friction and the wall roughness. Here, we investigate a highly turbulent TC flow, with a hydrodynamically fully rough, rotating inner cylinder, while the outer cylinder is kept smooth and stationary. We carry out particle image velocimetry (PIV) measurements in the Twente Turbulent Taylor–Couette (T3C) facility with Reynolds numbers in the range of 4.6 × 105 < Rei < 1.77 × 106. From these we find, while taking into account the influence of the curved walls on the turbulence, that the observed effects of a hydrodynamically fully rough surface are similar for TC turbulence and flat-plate turbulent boundary layer flows (BL). Hence, the equivalent sand grain height ks, that characterizes the drag properties of a rough surface, is similar for both flow geometries. Next, we obtain the dependence of the torque (skin-friction drag) on the Reynolds number for a given wall roughness, characterized by ks, and find agreement with the same results derived from PIV measurements within 5%. Our findings demonstrate that global torque measurements in the TC facility could be well suited to reliably deduce wall-drag properties for any rough surface.

Published
2021

33. Calculation of the mean velocity profile for strongly turbulent Taylor–Couette flow at arbitrary radius ratios

Author

Berghout, P, Verzicco, R, Stevens, RJAM, Lohse, D, Chung, D, Berghout, P, Verzicco, R, Stevens, RJAM, Lohse, D, and Chung, D

Abstract

Taylor–Couette (TC) flow is the shear-driven flow between two coaxial independently rotating cylinders. In recent years, high-fidelity simulations and experiments revealed the shape of the streamwise and angular velocity profiles up to very high Reynolds numbers. However, due to curvature effects, so far no theory has been able to correctly describe the turbulent streamwise velocity profile for a given radius ratio, as the classical Prandtl–von Kármán logarithmic law for turbulent boundary layers over a flat surface at most fits in a limited spatial region. Here, we address this deficiency by applying the idea of a Monin–Obukhov curvature length to turbulent TC flow. This length separates the flow regions where the production of turbulent kinetic energy is governed by pure shear from that where it acts in combination with the curvature of the streamlines. We demonstrate that for all Reynolds numbers and radius ratios, the mean streamwise and angular velocity profiles collapse according to this separation. We then develop the functional form of the velocity profile. Finally, using the newly developed angular velocity profiles, we show that these lead to an alternative constant in the model proposed by Cheng et al. (J. Fluid Mech., vol. 890, 2020, A17) for the dependence of the torque on the Reynolds number, or, in other words, of the generalized Nusselt number (i.e. the dimensionless angular velocity transport) on the Taylor number.

Published
2020

37. A method for pressure calculation in ball valves containing bubbles

Author

van Lookeren Campagne, C., Nicodemus, R., de Bruin, G.J., and Lohse, D.

Subjects
Civil engineering -- Research, Hydraulic engineering -- Research, Bubbles -- Models, Ball valves -- Research, Hydrostatic pressure -- Measurement, Engineering and manufacturing industries, Science and technology
Abstract

A method of analyzing bubbly flow in a ball valve in a hydraulic circuit is presented. The dynamics of a single bubble can be well described by a quasi-static approximation of the Rayleigh-Plesset equation. Hence the presence of bubbles in low volume fractions can be modeled through an effective compressibility of the flow, which is easy to implement in commercial CFD packages. In the sample valve, a volume fraction of 4% air bubbles results in a mass flux reduction of up to 10%, as the bubbles expand due to the pressure drop in the valve and partly block it.

Published
2002

39. Complex fluids

Author

Aranson, I., primary, Blair, D., additional, Vorobieff, P., additional, Metcalfe, G., additional, Shinbrot, T., additional, McCarthy, J. J., additional, Ottino, J. M., additional, Olafsen, J. S., additional, Urbach, J. S., additional, Mikkelsen, R., additional, Versluis, M., additional, Koene, E., additional, van der Bruggert, G.-W., additional, Lohse, D., additional, Tirumkudulu, M., additional, Tripathi, A., additional, Acrivos, A., additional, Walther, J. H., additional, Lee, S.-S., additional, Koumoutsakos, P., additional, Eames, I., additional, Dalziel, S. B., additional, Anna, S. L., additional, Spiegelberg, H., additional, and McKinley, G. H., additional

Published
2004
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40. Heat transfer in rough-wall turbulent thermal convection in the ultimate regime

Author

MacDonald, M, Hutchins, N, Lohse, D, Chung, D, MacDonald, M, Hutchins, N, Lohse, D, and Chung, D

Abstract

Heat and momentum transfer in wall-bounded turbulent flow, coupled with the effects of wall roughness, is one of the outstanding questions in turbulence research. In the standard Rayleigh-Bénard problem for natural thermal convection, it is notoriously difficult to reach the so-called ultimate regime in which the near-wall boundary layers are turbulent. Following the analyses proposed by Kraichnan [Phys. Fluids 5, 1374 (1962)] and Grossmann and Lohse [Phys. Fluids 23, 045108 (2011)], we instead utilize recent direct numerical simulations of forced convection over a rough wall in a minimal channel [MacDonald et al., J. Fluid Mech. 861, 138 (2019)] to directly study these turbulent boundary layers. We focus on the heat transport (in dimensionless form, the Nusselt number Nu) or equivalently the heat transfer coefficient (the Stanton number Ch). Extending the analyses of Kraichnan and Grossmann and Lohse, we assume logarithmic temperature profiles with a roughness-induced shift to predict an effective scaling of Nu∼Ra0.42, where Ra is the dimensionless temperature difference, corresponding to Ch∼Re−0.16, where Re is the centerline Reynolds number. This is pronouncedly different from the skin-friction coefficient Cf, which in the fully rough turbulent regime is independent of Re, due to the dominant pressure drag. In rough-wall turbulence, the absence of the analog to pressure drag in the temperature advection equation is the origin for the very different scaling properties of the heat transfer as compared to the momentum transfer. This analysis suggests that, unlike momentum transfer, the asymptotic ultimate regime, where Nu∼Ra1/2, will never be reached for heat transfer at finite Rayleigh number.

Published
2019

42. Heat transport in two-phase vertical natural convection using an Euler–Lagrange approach

Author

Ng, C. S., Spandan, V., Lohse, D., Verzicco, R., Lau, Timothy C.W., Kelso, Richard M., and Physics of Fluids

Subjects
Physics::Fluid Dynamics
Abstract

We present numerical results of dispersed droplets in vertical natural convection (VNC) flow, which is a buoyancy driven flow between differentially heated vertical walls. Our focus is to study the effects of droplets on the local statistics of heat transport in natural convection, where heat transport enhancement due to bubbles has recently been reported [5]. Our numerical simulations are fully-resolved and based on an Euler–Lagrange approach with two phases: the first is the carrier phase (liquid), which is solved by a second-order accurate finite-difference scheme and marched in time using a fractional-step approach; the second is the dispersed phase (droplets) that are much larger than the Kolmogorov length scale. The interfacial droplet boundaries and deformations are modelled by an immersed boundary method and an interaction potential approach, respectively. We show that the heat flux is slightly enhanced for the Rayleigh number range 1.3×108–2.3×109 and Prandtl number of 7, which can be attributed to droplet induced mixing.

Published
2018

43. Drop impact on solid substrates

Author

Gelderblom, H., Visser, C. W., Sun, C., Lohse, D., Bocquet, Lydéric, Quéré, David, Witten, Thomas A., Cugliandolo, Leticia F., Physics of Fluids, and Fluids and Flows

Subjects
Entrapment, Materials science, Drop (liquid), Bubble, Spreading dynamics, Mechanics, Drop impact, Drop deformation, Air bubble entrapment
Abstract

This chapter deals with drop impact and, in particular, two aspects: the deformation of the drop and the subsequent entrapment of air bubbles, and the drop spreading dynamics.

Published
2017

45. Evaporating pure, binary and ternary droplets: Thermal effects and axial symmetry breaking

Author

Diddens, C., Tan, H., Lv, P., Versluis, M., Kuerten, J.G.M., Zhang, X., Lohse, D., Diddens, C., Tan, H., Lv, P., Versluis, M., Kuerten, J.G.M., Zhang, X., and Lohse, D.

Abstract

The Greek aperitif Ouzo is not only famous for its specific anise-flavoured taste, but also for its ability to turn from a transparent miscible liquid to a milky-white coloured emulsion when water is added. Recently, it has been shown that this so-called Ouzo effect, i.e. the spontaneous emulsification of oil microdroplets, can also be triggered by the preferential evaporation of ethanol in an evaporating sessile Ouzo drop, leading to an amazingly rich drying process with multiple phase transitions (Tan et al., Proc. Natl Acad. Sci. USA, vol. 113 (31), 2016, pp. 8642-8647). Due to the enhanced evaporation near the contact line, the nucleation of oil droplets starts at the rim which results in an oil ring encircling the drop. Furthermore, the oil droplets are advected through the Ouzo drop by a fast solutal Marangoni flow. In this article, we investigate the evaporation of mixture droplets in more detail, by successively increasing the mixture complexity from pure water over a binary water-ethanol mixture to the ternary Ouzo mixture (water, ethanol and anise oil). In particular, axisymmetric and full three-dimensional finite element method simulations have been performed on these droplets to discuss thermal effects and the complicated flow in the droplet driven by an interplay of preferential evaporation, evaporative cooling and solutal and thermal Marangoni flow. By using image analysis techniques and micro-particle-image-velocimetry measurements, we are able to compare the numerically predicted volume evolutions and velocity fields with experimental data. The Ouzo droplet is furthermore investigated by confocal microscopy. It is shown that the oil ring predominantly emerges due to coalescence.

Published
2017

46. Ultrafast imaging method to measure surface tension and viscosity of inkjet printed droplets in flight

Author

Staat, H.J.J., van der Bos, A., van den Berg, Marc, Reinten, H., Wijshoff, H.M.A, Versluis, M., Lohse, D., Staat, H.J.J., van der Bos, A., van den Berg, Marc, Reinten, H., Wijshoff, H.M.A, Versluis, M., and Lohse, D.

Abstract

In modern drop-on-demand inkjet printing, the jetted droplets contain a mixture of solvents, pigments and surfactants. In order to accurately control the droplet formation process, its in-flight dynamics, and deposition characteristics upon impact at the underlying substrate, it is key to quantify the instantaneous liquid properties of the droplets during the entire inkjet printing process. An analysis of shape oscillation dynamics is known to give direct information of the local liquid properties of millimetersized droplets and bubbles. Here, we apply this technique to measure the surface tension and viscosity of micrometer-sized inkjet droplets in flight by recording the droplet shape oscillations microseconds after pinch-off from the nozzle. From the damped oscillation amplitude and frequency we deduce the viscosity and surface tension, respectively. With this ultrafast imaging method we study the role of surfactants in freshly made inkjet droplets in flight and compare to complementary techniques for dynamic surface tension measurements.

Published
2017

47. Self-wrapping of an ouzo drop induced by evaporation on a superamphiphobic surface

Author

Tan, H., Diddens, C., Versluis, M., Butt, H.J., Lohse, D., Zhang, X., Tan, H., Diddens, C., Versluis, M., Butt, H.J., Lohse, D., and Zhang, X.

Abstract

Evaporation of multi-component drops is crucial to various technologies and has numerous potential applications because of its ubiquity in nature. Superamphiphobic surfaces, which are both superhydrophobic and superoleophobic, can give a low wettability not only for water drops but also for oil drops. In this paper, we experimentally, numerically and theoretically investigate the evaporation process of millimetric sessile ouzo drops (a transparent mixture of water, ethanol, and trans-anethole) with low wettability on a superamphiphobic surface. The evaporation-triggered ouzo effect, i.e. the spontaneous emulsification of oil microdroplets below a specific ethanol concentration, preferentially occurs at the apex of the drop due to the evaporation flux distribution and volatility difference between water and ethanol. This observation is also reproduced by numerical simulations. The volume decrease of the ouzo drop is characterized by two distinct slopes. The initial steep slope is dominantly caused by the evaporation of ethanol, followed by the slower evaporation of water. At later stages, thanks to Marangoni forces the oil wraps around the drop and an oil shell forms. We propose an approximate diffusion model for the drying characteristics, which predicts the evaporation of the drops in agreement with experiment and numerical simulation results. This work provides an advanced understanding of the evaporation process of ouzo (multi-component) drops.

Published
2017

48. Taylor-Couette turbulence at radius ratio $\eta=0.5$: scaling, flow structures and plumes

Author

van der Veen, R., Huisman, S., Merbold, S., Harlander, U., Egbers, C., Lohse, D., and Sun, C.

Subjects
Physics::Fluid Dynamics, Physics - Fluid Dynamics
Abstract

Using high-resolution particle image velocimetry we measure velocity profiles, the wind Reynolds number and characteristics of turbulent plumes in Taylor-Couette flow for a radius ratio of 0.5 and Taylor number of up to $6.2\cdot10^9$. The extracted angular velocity profiles follow a log-law more closely than the azimuthal velocity profiles due to the strong curvature of this $\eta=0.5$ setup. The scaling of the wind Reynolds number with the Taylor number agrees with the theoretically predicted 3/7-scaling for the classical turbulent regime, which is much more pronounced than for the well-explored $\eta=0.71$ case, for which the ultimate regime sets in at much lower Ta. By measuring at varying axial positions, roll structures are found for counter-rotation while no clear coherent structures are seen for pure inner cylinder rotation. In addition, turbulent plumes coming from the inner and outer cylinder are investigated. For pure inner cylinder rotation, the plumes in the radial velocity move away from the inner cylinder, while the plumes in the azimuthal velocity mainly move away from the outer cylinder. For counter-rotation, the mean radial flow in the roll structures strongly affects the direction and intensity of the turbulent plumes. Furthermore, it is experimentally confirmed that in regions where plumes are emitted, boundary layer profiles with a logarithmic signature are created.

Published
2015

49. Phase diagram of turbulent Taylor-Couette flow

Author

Lohse, D., Mónico, R. O., Poel, E. P., Grossmann, S., ROBERTO VERZICCO, and Physics of Fluids

Subjects
Physics::Fluid Dynamics
Abstract

We will present the results of our recent numerical work on the nature of the phase diagram of turbulent Taylor-Couette (TC) flow, both with co- and counterrotating cylinder [3]. The work can be seen as the extension of the famous experimental Andereck et al. [1] phase diagram for Taylor-Couette flow just above the onset of instabilities, towards the ultimate turbulence regime, and now obtained numerically. In particular, we will understand when and why optimal transport of angular velocity from the inner to the outer cylinder is achieved and how this is connected to the angular velocity profile and the structures in the flow.

Published
2015

50. Direct numerical simulations of two-phase Taylor-Couette turbulence

Author

Spandan, V., Ostilla-Monico, R., ROBERTO VERZICCO, Lohse, D., and Physics of Fluids

Subjects
Physics::Fluid Dynamics
Abstract

Two-phase Taylor Couette flow is simulated using the Euler-Lagrange approach, where the dispersed phase is treated as point particles with effective forces such as drag, lift, added mass and buoyancy acting on them. Two-way coupling is implemented between the carrier and the dispersed phase allowing us to study the interaction between the point like particles and the large scale flow structure in the carrier phase. Light buoyant particles are observed to be very effective in disrupting the coherent Taylor rolls, thus reducing the overall dissipation in the system and the overall driving torque.

Published
2015

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