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1. Anomalous Dynamics of a Liquid Corner Film

Author

Moura, Marcel, Kern, Vanessa, Måløy, Knut Jørgen, Carlson, Andreas, and Flekkøy, Eirik G.

Subjects
Physics - Fluid Dynamics
Abstract

Measuring the rheology of liquids typically requires precise control over shear rates and stresses. However, we demonstrate that the features of a power-law fluid can be predicted by simply observing the capillary spreading dynamics of viscous droplets within a wedge-shaped geometry. By considering the influence of capillary and viscous forces within this geometry, we show that the spreading dynamics can be described by a nonlinear diffusion equation. Analytical predictions indicate subdiffusive behavior, establishing a direct relationship between the diffusion exponent and the rheological exponent, which is also corroborated by experimental results. Since this relationship is independent of flow details, it provides robust predictions for the rheological properties of power-law fluids.

Published
2025

2. Singular viscoelastic perturbation to soft lubrication

Author

Bharti, Bharti, Ferreira, Quentin, Jha, Aditya, Carlson, Andreas, Dean, David S., Amarouchene, Yacine, Chan, Tak Shing, and Salez, Thomas

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics, Physics - Classical Physics
Abstract

Soft lubrication has been shown to drastically affect the mobility of an object immersed in a viscous fluid in the vicinity of a purely elastic wall. In this theoretical study, we develop a minimal model incorporating viscoelasticity, carrying out a perturbation analysis in both the elastic deformation of the wall and its viscous damping. Our approach reveals the singular-perturbation nature of viscoelasticity to soft lubrication. Numerical resolution of the resulting non-linear, singular and coupled equations of motion reveals peculiar effects of viscoelasticity on confined colloidal mobility, opening the way towards the description of complex migration scenarios near realistic polymeric substrates and biological membranes.

Published
2024

3. Plateau-Rayleigh instability of a soft layer coated on a rigid cylinder

Author

Bharti, Carlson, Andreas, and Chan, Tak Shing

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

We study the Plateau-Rayleigh instability of a viscoelastic soft solid layer coated on a rigid cylinder i.e., a soft fibre with a rigid core. The onset of instability is examined using a linear stability analysis. We find that increasing the rigid cylinder radius reduce the growth rate of the fastest growing mode. For each rigid cylinder radius, a critical elastocapillary number is found below which all wavelengths of disturbances are stable. The critical value for a soft fibre with a thick rigid cylindrical core can be several orders of magnitudes larger than that for a totally soft fibre (no rigid core), which highlights the strong stabilizing effect of the rigid core on the system. Increasing the relaxation timescale of the viscoelastic material also slows down the growth of disturbance, but has no effect on the critical elastocapillary number. Interestingly, the wavelength of the fastest growing mode is independent of the rigid cylinder radius for the purely elastic case.

Published
2024

4. Spreading and engulfment of a viscoelastic film onto a Newtonian droplet

Author

Zhao, Chunheng, Lee, Taehun, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

We use the conservative phase-field lattice Boltzmann method to investigate the dynamics when a Newtonian droplet comes in contact with an immiscible viscoelastic liquid film. The dynamics of the three liquid phases are explored through numerical simulations, with a focus on illustrating the contact line dynamics and the viscoelastic effects described by the Oldroyd-B model. The droplet dynamics are contrasted with the case of a Newtonian fluid film. The simulations demonstrate that when the film is viscoelastic, the droplet dynamics become insensitive to the film thickness when the polymer viscosity and relaxation time are large. A viscoelastic ridge forms at the moving contact line, which evolves with a power-law dependence on time. By rescaling the interface profile of the ridge using its height and width, it appears to collapse onto a similar shape. Our findings reveal a strong correlation between the viscoelastic stress and the interface shape near the contact line.

Published
2024

5. Crowding-Regulated Binding of Divalent Biomolecules

Author

Skóra, Tomasz, Janssen, Mathijs, Carlson, Andreas, and Kondrat, Svyatoslav

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

Macromolecular crowding affects biophysical processes as diverse as diffusion, gene expression, cell growth, and senescence. Yet, there is no comprehensive understanding of how crowding affects reactions, particularly multivalent binding. Herein, we use scaled particle theory and develop a molecular simulation method to investigate the binding of monovalent to divalent biomolecules. We find that crowding can increase or reduce cooperativity--the extent to which the binding of a second molecule is enhanced after binding a first molecule--by orders of magnitude, depending on the sizes of the involved molecular complexes. Cooperativity generally increases when a divalent molecule swells and then shrinks upon binding two ligands. Our calculations also reveal that, in some cases, crowding enables binding that does not occur otherwise. As an immunological example, we consider Immunoglobulin G-antigen binding and show that crowding enhances its cooperativity in bulk but reduces it when an Immunoglobulin G binds antigens on a surface.

Published
2024
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6. Plateau-Rayleigh instability of a viscous film on a soft fiber

Author

Bharti, Bharti, Carlson, Andreas, Chan, Tak Shing, and Salez, Thomas

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Classical Physics
Abstract

We theoretically study the Plateau-Rayleigh instability of a thin viscous film covering a fiber consisting of a rigid cylindrical core coated with a thin compressible elastic layer. We develop a soft-lubrication model, combining the capillary-driven flow in the viscous film to the elastic deformation of the soft coating, within the Winkler-foundation framework. We perform a linear-stability analysis and derive the dispersion relation. We find that the growth rate is larger when the soft coating is more compliant. As such, softness acts as a destabilising factor. In contrast, increasing the thickness of the soft coating reduces the growth rate, due to the dominating geometrical effect.

Published
2023

7. Coalescence of elastic blisters filled with a viscous fluid

Author

Sæter, Torstein, Pedersen, Christian, Snoeijer, Jacco H., Salez, Thomas, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

Pockets of viscous fluid coalescing beneath an elastic plate are encountered in a wide range of natural phenomena and engineering processes, spanning across scales. As the pockets merge, a bridge is formed with a height increasing as the plate relaxes. We study the spatiotemporal dynamics of such an elasto-hydrodynamic coalescence process by combining experiments, lubrication theory and numerical simulations. The bridge height exhibits an exponential growth with time, which corresponds to a self-similar solution of the bending-driven thin-film equation. We address this unique self-similarity and the self-similar shape of the bridge, both of which are corroborated in numerical simulations and experiments.

Published
2023

8. Static wetting of a barrel-shaped droplet on a soft-layer-coated fiber

Author

Zheng, Bo Xue, Pedersen, Christian, Carlson, Andreas, and Chan, Tak Shing

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Classical Physics, Physics - Fluid Dynamics
Abstract

A droplet can deform a soft substrate due to capillary forces when they are in contact. We study the static deformation of a soft solid layer coated on a rigid cylindrical fiber when an axisymmetric barrel-shaped droplet is embracing it. We find that the elastic deformation increases with decreasing rigid fiber radius. Significant disparities of deformation between the solid-liquid side and the solid-gas side are found when their solid surface tensions are different. When the coated layer is soft enough and the rigid fiber radius is less than the thickness of the coated layer, pronounced displacement oscillations are observed. Such slow decay of deformation with distances from the contact line position suggests a possible long-range interaction between droplets on a soft-layer-coated fiber., Comment: 8 pages, 6 figures

Published
2023

9. Instability and rupture of sheared viscous liquid nanofilms

Author

Dhaliwal, Vira, Pedersen, Christian, Kadri, Kheireddine, Miquelard-Garnier, Guillaume, Sollogoub, Cyrille, Peixinho, Jorge, Salez, Thomas, and Carlson, Andreas

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Fluid Dynamics
Abstract

Liquid nanofilms are ubiquitous in nature and technology, and their equilibrium and out-of-equilibrium dynamics are key to a multitude of phenomena and processes. We numerically study the evolution and rupture of viscous nanometric films, incorporating the effects of surface tension, van der waals forces, thermal fluctuations and viscous shear. We show that thermal fluctuations create perturbations that can trigger film rupture, but they do not significantly affect the growth rate of the perturbations. The film rupture time can be predicted from a linear stability analysis of the governing thin film equation, by considering the most unstable wavelength and the thermal roughness. Furthermore, applying a sufficiently large unidirectional shear can stabilise large perturbations, creating a finite-amplitude travelling wave instead of film rupture. In contrast, in three dimensions, unidirectional shear does not inhibit rupture, as perturbations are not suppressed in the direction perpendicular to the applied shear. However, if the direction of shear varies in time, the growth of large perturbations is prevented in all directions, and rupture can hence be impeded.

Published
2023

10. Influence of wind on a viscous liquid film flowing down a thread

Author

Cazaubiel, Annette and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

We investigate experimentally the effect of wind on the dynamics of a viscous liquid film flowing down a thread. The liquid film is well-known to destabilize into an axisymmetric bead-like pattern in stagnant air. When the flowing film is exposed to side-wind, the beads are pushed downstream breaking the symmetry leading to a modification of the film flow. The viscous dissipation in the liquid film decreases with increasing side-wind, leading to a faster slide speed of the liquid beads. The inertia in the film is then increased, which can induce a regime shift, triggering an instability. When the film becomes unstable, it switches from a periodic pattern of equally sized liquid beads to an irregular film pattern where large beads collide with smaller ones.

Published
2022

11. Surface and Bulk Relaxation of Vapour-Deposited Polystyrene Glasses

Author

Yin, Junjie, Pedersen, Christian, Thees, Michael, Carlson, Andreas, Salez, Thomas, and Forrest, James A

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter, Physics - Classical Physics, Physics - Fluid Dynamics
Abstract

We have studied the liquid-like response of the surface of vapour-deposited glassy films of polystyrene to the introduction of gold nanoparticles on the surface. The build-up of polymer material was measured as a function of time and temperature for both as-deposited films, as well as films that have been rejuvenated to become normal glasses cooled from the equilibrium liquid. The temporal evolution of the surface profile is well described by the characteristic power law of capillary-driven surface flows. In all cases, the surface evolution of the as-deposited films and the rejuvenated films are enhanced compared to bulk and are not easily distinguishable from each other. The temperature dependence of the measured relaxation times determined from the surface evolution is found to be quantitatively comparable to similar studies for high molecular weight spincast polystyrene. Comparisons to numerical solutions of the glassy thin film equation provide quantitative estimates of the surface mobility. For temperatures sufficiently close to the glass-transition temperature, particle embedding is also measured and used as a probe of bulk dynamics, and in particular bulk viscosity.

Published
2022
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12. Sliding, vibrating and swinging droplets on an oscillating fibre

Author

Poulain, Stéphane and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

We study experimentally the dynamics of a water droplet on a tilted and vertically oscillating rigid fibre. As we vary the frequency and amplitude of the oscillations the droplet transitions between different modes: harmonic pumping, subharmonic pumping, a combination of rocking and pumping modes, and a combination of pumping and swinging modes. We characterise these responses and report how they affect the droplet's sliding speed along the fibre. The droplet swinging mode is explained by a minimal model making an analogy between the droplet and a forced elastic pendulum., Comment: corrected authors

Published
2022
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13. Engulfment of a drop on solids coated by thin and thick fluid films

Author

Zhao, Chunheng, Kern, Vanessa R., Carlson, Andreas, and Lee, Taehun

Subjects
Physics - Fluid Dynamics
Abstract

When an aqueous drop contacts an immiscible oil film, it displays complex interfacial dynamics. Upon contact the oil spreads onto the drop's liquid-air interface, first forming a curvature that drives an apparent drop spreading motion and later fully engulfing the drop. We study this flow using both 3-phase Lattice-Boltzmann simulations based on the conservative phase field model and experiments. Inertially and viscously limited dynamics are explored using the Ohnesorge number $Oh$ as a function of $R/H$, the ratio between the initial drop radius $R$ and the film height $H$. Both regimes show that the apparent spreading radius $r$ is fairly independent of the film height, and scales with time $T$ as $r\sim T^{1/2}$ for $Oh\ll 1$ and for $Oh\gg 1$ as $r\sim T^{2/5}$. For $Oh\gg 1$ we show experimentally that this immiscible apparent spreading motion is analogous with the miscible drop-film coalescence case. Contrary to the apparent spreading, however, we find that the late time engulfment dynamics and final interface profiles are significantly affected by the ratio of $H/R$.

Published
2022
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14. Near-critical spreading of droplets

Author

Saiseau, Raphael, Pedersen, Christian, Benjana, Anwar, Carlson, Andreas, Delabre, Ulysse, Salez, Thomas, and Delville, Jean-Pierre

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Statistical Mechanics, Physics - Chemical Physics, Physics - Fluid Dynamics
Abstract

We study the spreading of droplets in a near-critical phase-separated liquid mixture, using a combination of experiments, lubrication theory and finite-element numerical simulations. The classical Tanner's law describing the spreading of viscous droplets is robustly verified when the critical temperature is neared. Furthermore, the microscopic cut-off length scale emerging in this law is obtained as a single free parameter for each given temperature. In total-wetting conditions, this length is interpreted as the thickness of the thin precursor film present ahead of the apparent contact line. The collapse of the different evolutions onto a single Tanner-like master curve demonstrates the universality of viscous spreading before entering in the fluctuation-dominated regime. Finally, our results reveal a counter-intuitive and sharp thinning of the precursor film when approaching the critical temperature, which is attributed to the vanishing spreading parameter at the critical point.

Published
2022
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15. Experimental and numerical investigation of bubble migration in shear flow: deformability-driven chaining and repulsion

Author

Feneuil, Blandine, Iqbal, Kazi Tassawar, Jensen, Atle, Brandt, Luca, Tammisola, Outi, and Carlson, Andreas

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

We study the interaction-induced migration of bubbles in shear flow and observe that bubbles suspended in elastoviscoplastic emulsions organise into chains aligned in the flow direction, similarly to particles in viscoelastic fluids. To investigate the driving mechanism, we perform experiments and simulations on bubble pairs, using suspending fluids with different rheological properties. First, we notice that, for all fluids, the interaction type depends on the relative position of the bubbles. If they are aligned in the vorticity direction, they repel, if not, they attract each other. The simulations show a similar behavior in Newtonian fluids as in viscoelastic and elastoviscoplastic fluids, as long as the capillary number is sufficiently large. This shows that the interaction-related migration of the bubbles is strongly affected by the bubble deformation. We suggest that the cause of migration is the interaction between the heterogeneous pressure fields around the deformed bubbles, due to capillary pressure., Comment: 20 pages, 19 figures

Published
2022

16. Viscoplastic sessile drop coalescence

Author

Kern, Vanessa R., Sæter, Torstein, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

The evolution of the liquid bridge formed between two coalescing sessile yield-stress drops is studied experimentally. We find that the height of the bridge evolves similar to a viscous Newtonian fluid, $h_0\sim t$, before arresting at long time prior to minimizing its liquid/gas interfacial energy. We numerically solve for the final arrested profile shape and find it depends on the fluid's yield stress $\tau_y$ and coalescence angle $\alpha$, represented by the Bingham number $\tau_y h_{drop} / \sigma$ modified by the drop's height-width aspect ratio. We present a scaling argument for the bridge's temporal evolution using the length scale found from an analysis of the arrested shape as well as from the similarity solution derived for the bridge's evolution., Comment: 9 pages, 9 figures

Published
2022

17. Growth of a viscoplastic blister underneath an elastic sheet

Author

Sæter, Torstein, Galland, Olivier, Feneuil, Blandine, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

Inspired by the formation of geological structures as earth's crust deforms by magmatic intrusions, we investigate the elastohydrodynamic growth of a viscoplastic blister under an elastic sheet. By combining experiments, scaling analysis and numerical simulations we reveal a new regime for the growth of the blister's height $\sim t^{5/9}$ and radius $\sim t^{2/9}$. A plug like flow inside the blister dictates its dynamics, whereas the blister takes a quasi-static self-similar shape given by a balance in the pressure gradient induced by bending of the elastic sheet and the fluid's yield stress., Comment: 4 pages, 3 figures

Published
2022
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18. Elastic modulus measurements of cooked Lutefisk

Author

Feneuil, Blandine, Lillebø, Eirik Strøm, Honstad, Christian Larris, Jensen, Atle, and Carlson, Andreas

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Lutefisk is a traditional Norwegian Christmas dish, made of dry cod soaked in a lye solution before re-hydrated. We report measurements of the tissue softness of cooked Lutefisk. Surprisingly, we find that the elastic modulus does not seem to depend heavily on cooking time, cooking temperature and the amount of salt, but depends instead mainly on the size of the fish fillets and the period of fishing. Although the salting and cooking of the Lutefisk affects strongly the visual aspect of the fish fillets, these changes are not measurable with a rheometer., Comment: 14 pages, 6 figures

Published
2021
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19. Multiple droplets on a conical fiber: formation, motion, and droplet mergers

Author

Lee, Carmen L., Chan, Tak Shing, Carlson, Andreas, and Dalnoki-Veress, Kari

Subjects
Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter
Abstract

Small droplets on slender conical fibers spontaneously move along the fiber due to capillary action. The droplet motion depends on the geometry of the cone, the surface wettability, the surface tension, the viscosity, and the droplet size. Here we study with experiments and numerical simulations, the formation, spontaneous motion, and the eventual merger, of multiple droplets on slender conical fibers as they interact with each other. The droplet size and their spacing on the fibre is controlled by the Plateau-Rayleigh instability after dip-coating the conical fiber. Once these droplets are formed on the fiber, they spontaneously start to move. Since droplets of different size move with different speeds, they effectively coarsen the droplet patterning by merging on the fiber. The droplet merging process affects locally the droplet speed and alters the spatiotemporal film deposition on the fiber., Comment: 7 pages, 7 figures

Published
2021

20. Droplet settling on solids coated with a soft layer

Author

Poulain, Stéphane and Carlson, Andreas

Subjects
Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter
Abstract

Gravitational settling of a droplet in air onto a soft substrate is a ubiquitous event relevant to many natural processes and engineering applications. We study this phenomenon by developing a three-phase lubrication model of droplet settling onto a solid substrate coated by a thin soft layer represented by a viscous film, an elastic compressible layer and an elastic sheet supported by a viscous film. By combining scaling analysis, analytical methods, and numerical simulations we elucidate how the resulting droplet dynamics is affected by the nature of the soft layer. We show that these soft layers can significantly affect the droplet shape during gravitational settling. When there is a linear response of the deformations of the soft layer, the air layer takes longer to drain as compared to the case of a droplet settling onto a rigid substrate. Our results provide new insight into the coupled interactions between droplets and solids coated by a thin film of a soft material., Comment: 26 pages, 13 figures, 1 table

Published
2021
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21. Nanobubble-induced flow of immersed glassy polymer films

Author

Pedersen, Christian, Ren, Shuai, Wang, Yuliang, Carlson, Andreas, and Salez, Thomas

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter, Physics - Classical Physics
Abstract

We study the free-surface deformation dynamics of an immersed glassy thin polymer film supported on a substrate, induced by an air nanobubble at the free surface.We combine analytical and numerical treatments of the glassy thin film equation, resulting from the lubrication approximation applied to the surface mobile layer of the glassy film, under the driving of an axisymmetric step function in the pressure term accounting for the nanobubble's Laplace pressure. Using the method of Green's functions, we derive a general solution for the film profile. We show that the lateral extent of the surface perturbation follows an asymptotic viscocapillary power-law behaviour in time, and that the film's central height decays logarithmically in time in this regime. This process eventually leads to film rupture and dewetting at finite time, for which we provide an analytical prediction exhibiting explicitly the dependencies in surface mobility, film thickness and bubble size, among others. Finally, using finite-element numerical integration, we discuss how non-linear effects induced by the curvature and film profile can affect the evolution.

Published
2021

22. Universal Self-Similar Attractor in the Bending-Driven Leveling of Thin Viscous Films

Author

Pedersen, Christian, Salez, Thomas, and Carlson, Andreas

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter, Physics - Classical Physics
Abstract

We study theoretically and numerically the bending-driven leveling of thin viscous films within the lubrication approximation. We derive the Green's function of the linearized thin-film equation and further show that it represents a universal self-similar attractor at long times. As such, the rescaled perturbation of the film profile converges in time towards the rescaled Green's function, for any summable initial perturbation profile. In addition, for stepped axisymmetric initial conditions, we demonstrate the existence of another, short-term and one-dimensional-like self-similar regime. Besides, we characterize the convergence time towards the long-term universal attractor in terms of the relevant physical and geometrical parameters, and provide the local hydrodynamic fields and global elastic energy in the universal regime as functions of time. Finally, we extend our analysis to the non-linear thin-film equation through numerical simulations.

Published
2020
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23. Film coating by directional droplet spreading on fibers

Author

Chan, Tak Shing, Lee, Carmen L., Pedersen, Christian, Dalnoki-Veress, Kari, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

Plants and insects use slender conical structures to transport and collect small droplets, which are propelled along the conical structures due to capillary action. These droplets can deposit a fluid film during their motion, but despite its importance to many biological systems and industrial applications the properties of the deposited film are unknown. We characterise the film deposition by developing an asymptotic analysis together with experimental measurements and numerical simulations based on the lubrication equation. We show that the deposited film thickness depends significantly on both the fiber radius and the droplet size, highlighting that the coating is affected by finite size effects relevant to film deposition on fibres of any slender geometry. We demonstrate that by changing the droplet size, while the mean fiber radius and the Capillary number are fixed, the thickness of the deposited film can change by an order of magnitude or more. We show that self-propelled droplets have significant potential to create passively coated structures.

Published
2020
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24. Destabilization and phase separation of particle suspensions in emulsions

Author

Feneuil, Blandine, Jensen, Atle, and Carlson, Andreas

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Yield stress fluids are widely used in industrial application to arrest dense solid particles, which can be studied by using a concentrated emulsion as a model fluid. We show in experiments that particle sedimentation in emulsions cannot be predicted by the classical criterion for spheres embedded in a yield stress fluid. Phase separation processes take place, where a liquid layer forms and particle sedimentation is enhanced by the emulsion drainage. In addition, emulsion drainage can be arrested or enhanced by the amount of particles embedded in the emulsion. A minimal mathematical model is developed and solved in numerical simulations to describe the emulsion drainage in the presence of particles, which favorably compares with the experimental stability diagram and the sedimentation dynamics., Comment: 12 pages, 12 figures

Published
2020
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26. Soft nanobubbles can deform rigid glasses

Author

Ren, Shuai, Pedersen, Christian, Carlson, Andreas, Salez, Thomas, and Wang, Yuliang

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Confined glasses and their anomalous interfacial rheology raise important questions in fundamental research and numerous practical applications. In this Letter, we study the influence of interfacial air nanobubbles on the free surface of ultrathin high-molecular-weight glassy polystyrene films immersed in water, in ambient conditions. In particular, we reveal the counterintuitive fact that a soft nanobubble is able to deform the surface of a rigid glass, forming a nanocrater with a depth that increases with time. By combining in-situ atomic-force-microscopy measurements and a modified lubrication model for the liquid-like layer at the free surface of the glass, we demonstrate that the capillary pressure in the nanobubble together with the liquid-like layer at the free surface of the glass determine the spatiotemporal growth of the nanocraters. Finally, from the excellent agreement between the experimental profiles and the numerical solutions of the governing glassy thin-film equation, we are able to precisely extract the surface mobility of the glass. In addition to revealing and quantifying how surface nanobubbles deform immersed glasses, until the latter eventually dewet from their substrates, our work provides a novel, precise, and simple measurement of the surface nanorheology of glasses.

Published
2020
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27. Asymptotic regimes in elastohydrodynamic and stochastic leveling on a viscous film

Author

Pedersen, Christian, Niven, John, Salez, Thomas, Dalnoki-Veress, Kari, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter
Abstract

An elastic sheet that deforms near a solid substrate in a viscous fluid is a situation relevant to various dynamical processes in biology, geophysics and engineering. Here, we study the relaxation dynamics of an elastic plate resting on a thin viscous film that is supported by a solid substrate. By combining scaling analysis, numerical simulations and experiments, we identify asymptotic regimes for the elastohydrodynamic leveling of a surface perturbation of the form of a bump, when the flow is driven by either the elastic bending of the plate or thermal fluctuations. In both cases, two distinct regimes are identified when the bump height is either much larger or much smaller than the thickness of the pre-wetted viscous film. Our analysis reveals a distinct crossover between the similarity exponents with the ratio of the perturbation height to the film height., Comment: 10 pages, 6 figures

Published
2019

28. Curving to fly: Synthetic adaptation unveils optimal flight performance of whirling fruits

Author

Rabault, Jean, Fauli, Richard A., and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

Appendages of seeds, fruits and other diaspores (dispersal units) are essential for their wind dispersal, as they act as wings and enable them to fly. Whirling fruits generate an auto-gyrating motion from their sepals, a leaf like structure, which curve upwards and outwards, creating a lift force that counteracts gravitational force. The link of the fruit's sepal shape to flight performance, however, is as yet unknown. We develop a theoretical model and perform experiments for double-winged bio-mimetic 3D-printed fruits, where we assume that the plant has a limited amount of energy that it can convert into a mass to build sepals and, additionally, allow them to curve. Both hydrodynamic theory and experiments involving synthetic, double-winged fruits show that to produce a maximal flight time there is an optimal fold angle for the desiccated sepals. A similar sepal fold angle is found for a wide range of whirling fruits collected in the wild, highlighting that wing curvature can aid as an efficient mechanism for wind dispersal of seeds and may improve the fitness of their producers in the context of an ecological strategy., Comment: arXiv admin note: text overlap with arXiv:1811.12221

Published
2019
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29. Directional spreading of a viscous droplet on a conical fibre

Author

Chan, Tak Shing, Yang, Fan, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

If a droplet is placed on a substrate with a conical shape it spontaneously starts to spread in the direction of a growing fibre radius. We describe this capillary spreading dynamics by developing a lubrication approximation on a cone and by the perturbation method of matched asymptotic expansions. Our results show that the droplet appears to adopt a quasi-static shape and the predictions of the droplet shape and spreading velocity from the two mathematical models are in excellent agreement for a wide range of slip lengths, cone angles and equilibrium contact angles. At the contact line regions, a large pressure gradient is generated by the mismatch between the equilibrium contact angle and the apparent contact angle that maintains the viscous flow. It is the conical shape of the substrate that breaks the front/rear droplet symmetry in terms of the apparent contact angle, which is larger at the thicker part of the cone than that at its thinner part. Consequently, the droplet is predicted to move from the cone tip to its base, consistent with experimental observations.

Published
2019
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30. Wing fold angle determines the terminal descent velocity of double winged autorotating seeds, fruits and other diaspores

Author

Fauli, Richard A., Rabault, Jean, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

Wind dispersal of seeds is one essential mechanisms for plants to proliferate and to invade new territories. In this paper we present a methodology that combines 3D-printing, a minimal theoretical model and experiments to determine the shape of multi-winged autorotating seeds, fruits and other diaspores that provide them with the optimal wind dispersion potential i.e. minimal terminal descent velocity. Experiments are performed on 3D-printed synthetic fruits for a wide range of wing fold angles, base wing angles and wing loadings to determine how these affect the flight. Our experimental and theoretical model find an optimal wing fold angle that minimizes the descent velocity, which may be an important parameter that improves the fitness of these plants in an ecological strategy.

Published
2018
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32. Fluctuation assisted spreading of a fluid filled elastic blister

Author

Carlson, Andreas

Subjects
Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter
Abstract

In this theoretical and numerical study, we show how spatially extended fluctuations can influence and dominate the dynamics of a fluid filled elastic blister as is deforms onto a pre-wetted solid substrate. To describe the blister dynamics, we develop a stochastic elastohydrodynamic framework that couples the viscous flow, the elastic bending of the interface and the noise from the environment. We deploy a scaling analysis to find the elastohydrodynamic spreading law $\hat R\sim {\hat t}^{1/11}$ a direct analogue to the capillary spreading of drops, while the inclusion of noise in our model highlights that the dynamics speed-up significantly $\hat R\sim {\hat t}^{1/6}$ as local changes in curvature enhance the peeling of the elastic interface from the substrate. Moreover, our analysis identifies a distinct criterion for the transition between the deterministic and stochastic spreading regime, which is further illustrated by numerical simulations.

Published
2017
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34. Local dissipation limits the dynamics of impacting droplets on smooth and rough substrates

Author

Wang, Yuli, Amberg, Gustav, and Carlson, Andreas

Subjects
Physics - Fluid Dynamics
Abstract

A droplet that impacts onto a solid substrate deforms in a complex dynamics. To extract the principal mechanisms that dominate this dynamics we deploy numerical simulations based on the phase field method. Direct comparison with experiments suggests that a dissipation local to the contact line limits the droplet spreading dynamics and its scaled maximum spreading radius $\beta_\mathrm{max}$. By assuming linear response through a drag force at the contact line, our simulations rationalize experimental observations for droplet impact on both smooth and rough substrates, measured through a single contact line friction parameter $\mu_f$. Moreover, our analysis shows that at low and intermediate impact speeds dissipation at the contact line limits the dynamics and we describe $\beta_\mathrm{max}$ by the scaling law $\beta_\mathrm{max} \sim (Re \mu_\mathrm{l}/\mu_f)^{1/2}$ that is a function of the droplet viscosity ($\mu_\mathrm{l}$) and its Reynolds number ($Re$).

Published
2016
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37. Elastohydrodynamics of contact in adherent sheets

Author

Carlson, Andreas, Mandre, Shreyas, and Mahadevan, L.

Subjects
Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter
Abstract

Adhesive contact between a thin elastic sheet and a substrate in a liquid environment arises in a range of biological, physical and technological applications. By considering the dynamics of this process that naturally couples fluid flow, long wavelength elastic deformations and microscopic adhesion, and solving the resulting partial differential equation numerically, we uncover the short-time dynamics of the onset of adhesion and the long-time dynamics of a steady propagating adhesion front. Simple scaling laws corroborate our results for characteristic waiting-time for adhesive contact, as well as the speed of the adhesion front. A similarity analysis of the governing partial differential equation further allows us to determine the shape of a fluid filled bump ahead of the adhesion zone. Finally, our analysis yields the boundary conditions for the apparent elastohydrodynamic contact line, generalizing the well known conditions for static elastic contact while highlighting how microscale physics regularizes the dynamics of contact.

Published
2015

38. Similarity and singularity in adhesive elastohydrodynamic touchdown

Author

Carlson, Andreas and Mahadevan, L.

Subjects
Physics - Fluid Dynamics
Abstract

We consider the touchdown of an elastic sheet as it adheres to a wall, which has a dynamics that is limited by the viscous resistance provided by the squeeze flow of the intervening liquid trapped between the two solid surfaces. The dynamics of the sheet is described mathematically by elastohydrodynamic lubrication theory, coupling the elastic deformation of the sheet, the microscopic van der Waals adhesion and the viscous thin film flow. We use a combination of numerical simulations of the governing partial differential equation and a scaling analysis to describe the self-similar solution of the touchdown of the sheet as it approaches the wall. An analysis of the equation satisfied by the similarity variables in the vicinity of the touchdown event shows that an entire sequence of solutions are allowed. However, a comparison of these shows that only the fundamental similarity solution is observed in the time-dependent numerical simulations, consistent with the fact that it alone is stable. Our analysis generalizes similar approaches for rupture in capillary thin film hydrodynamics and suggests experimentally verifiable predictions for a new class of singular flows linking elasticity, hydrodynamics and adhesion.

Published
2015
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39. Elastohydrodynamics and kinetics of protein patterning in the immunological synapse

Author

Carlson, Andreas and Mahadevan, L.

Subjects
Physics - Biological Physics, Quantitative Biology - Subcellular Processes
Abstract

The cellular basis for the adaptive immune response during antigen recognition relies on a specialized protein interface known as the immunological synapse (IS). Understanding the biophysical basis for protein patterning by deciphering the quantitative rules for their formation and motion is an important aspect of characterizing immune cell recognition and thence the rules for immune system activation. We propose a minimal mathematical model for the physical basis of membrane protein patterning in the IS, which encompass membrane mechanics, protein binding kinetics and motion, and fluid flow in the synaptic cleft. Our theory leads to simple predictions for the spatial and temporal scales of protein cluster formation, growth and arrest as a function of membrane stiffness, rigidity and kinetics of the adhesive proteins, and the fluid in the synaptic cleft. Numerical simulations complement these scaling laws by quantifying the nucleation, growth and stabilization of proteins domains on the size of the cell. Direct comparison with experiment shows that passive elastohydrodynamics and kinetics of protein binding in the synaptic cleft can describe the short-time formation and organization of protein clusters, without evoking any active processes in the cytoskeleton. Despite the apparent complexity of the process, our analysis highlights the role of just two dimensionless parameters that characterize the spatial and temporal evolution of the protein pattern: a ratio of membrane elasticity to protein elasticity, and the ratio of a hydrodynamic time scale for fluid flow relative to the protein binding rate, and we present a simple phase diagram that encompasses the variety of patterns that can arise.

Published
2015
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40. Twisted fibers enable drop flow control and enhance fog capture.

Author

Kern, Vanessa R. and Carlson, Andreas

Subjects
*CAPILLARY flow, *FLUID mechanics, *FLUID flow, *HUMIDITY control, *FIBERS
Abstract

Drop-fiber interactions are fundamental to the operation of technologies such as atmospheric fog capture, oil filtration, refrigeration, and dehumidification. We demonstrate that by twisting together two fibers, a sliding drop's flow path can be controlled by tuning the ratio between its size and the twist wavelength. We find both experimentally and numerically that twisted fiber systems are able to asymmetrically stabilize drops, both enhancing drop transport speeds and creating a rich array of new flow patterns. We show that the passive flow control generated by twisting fibers allows for woven nets that can be "programmed" with junctions that predetermine drop interactions and can be anticlogging. Furthermore, it is shown that twisted fiber structures are significantly more effective at capturing atmospheric fog compared to straight fibers. [ABSTRACT FROM AUTHOR]

Published
2024
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44. Surface and bulk relaxation of vapor-deposited polystyrene glasses.

Author

Yin, Junjie, Pedersen, Christian, Thees, Michael F., Carlson, Andreas, Salez, Thomas, and Forrest, James A.

Subjects
POLYSTYRENE, BULK viscosity, LIQUID films, GOLD nanoparticles, MOLECULAR weights, THIN films
Abstract

We have studied the liquid-like response of the surface of vapor-deposited glassy films of polystyrene to the introduction of gold nanoparticles on the surface. The build-up of polymer material was measured as a function of time and temperature for both as-deposited films, as well as films that have been rejuvenated to become normal glasses cooled from the equilibrium liquid. The temporal evolution of the surface profile is well described by the characteristic power law of capillary-driven surface flows. In all cases, the surface evolution of the as-deposited films and the rejuvenated films is enhanced compared to bulk and is not easily distinguishable from each other. The temperature dependence of the measured relaxation times determined from the surface evolution is found to be quantitatively comparable to similar studies for high molecular weight spincast polystyrene. Comparisons to numerical solutions of the glassy thin film equation provide quantitative estimates of the surface mobility. For temperatures sufficiently close to the glass-transition temperature, particle embedding is also measured and used as a probe of bulk dynamics, and, in particular, bulk viscosity. [ABSTRACT FROM AUTHOR]

Published
2023
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46. Universality in dynamic wetting dominated by contact line friction

Author

Carlson, Andreas, Bellani, Gabriele, and Amberg, Gustav

Subjects
Physics - Fluid Dynamics
Abstract

We report experiments on the rapid contact line motion present in the early stages of capillary driven spreading of drops on dry solid substrates. The spreading data fails to follow a conventional viscous or inertial scaling. By integrating experiments and simulations, we quantify a contact line friction ($\mu_f$), which is seen to limit the speed of the rapid dynamic wetting. A scaling based on this contact line friction is shown to yield a universal curve for the evolution of the contact line radius as a function of time, for a range of fluid viscosities, drop sizes and surface wettabilities.

Published
2011
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48. Photo‐annealing of Microtissues Creates High‐Density Capillary Network Containing Living Matter in A Volumetric‐Independent Manner.

Author

Schot, Maik, primary, Becker, Malin, additional, Paggi, Carlo Alberto, additional, Gomes, Francisca, additional, Koch, Timo, additional, Gensheimer, Tarek, additional, Johnbosco, Castro, additional, Nogueira, Liebert Parreiras, additional, van der Meer, Andries, additional, Carlson, Andreas, additional, Haugen, Håvard, additional, and Leijten, Jeroen, additional

Published
2023
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