Your search keyword '"L. Deike"' showing total 15 results

1. A Mechanistic Sea Spray Generation Function Based on the Sea State and the Physics of Bubble Bursting

Author

L. Deike, B. G. Reichl, and F. Paulot

Subjects

aerosol, sea spray aerosol emission, bubble bursting, wave breaking, Geology, QE1-996.5, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Bubbles bursting at the ocean surface are an important source of ocean‐spray aerosol, with implications on radiative and cloud processes. Yet, very large uncertainties exist on the role of key physical controlling parameters, including wind speed, sea state and water temperature. We propose a mechanistic sea spray generation function that is based on the physics of bubble bursting. The number and mean droplet radius of jet and film drops is described by scaling laws derived from individual bubble bursting laboratory and numerical experiments, as a function of the bubble radius and the water physico‐chemical properties (viscosity, density and surface tension, all functions of temperature), with drops radii at production from 0.1 to 500 µm. Next, we integrate over the bubble size distribution entrained by breaking waves. Finally, the sea spray generation function is obtained by considering the volume flux of entrained bubbles due to breaking waves in the field constrained by the third moment of the breaking distribution (akin to the whitecap coverage). This mechanistic approach naturally integrates the role of wind and waves via the breaking distribution and entrained air flux, and a sensitivity to temperature via individual bubble bursting mechanisms. The resulting sea spray generation function has not been tuned or adjusted to match any existing data sets, in terms of magnitude of sea salt emissions and recently observed temperature dependencies. The remarkable coherence between the model and observations of sea salt emissions therefore strongly supports the mechanistic approach and the resulting sea spray generation function.

Published

2022

2. Speed and Acceleration of Droplets Generated by Breaking Wind‐Forced Waves

Author

M. A. Erinin, B. Néel, D. J. Ruth, M. Mazzatenta, R. D. Jaquette, F. Veron, and L. Deike

Subjects

Geophysics, General Earth and Planetary Sciences

Published

2022

3. High-resolution direct simulation of deep water breaking waves: transition to turbulence, bubbles and droplet production

Author

W. Mostert, S. Popinet, and L. Deike

Subjects

Physics::Fluid Dynamics, Mechanics of Materials, Mechanical Engineering, Applied Mathematics, Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, Physics - Fluid Dynamics, Condensed Matter Physics

Abstract

[Abridged]We present high-resolution three-dimensional direct numerical simulations of breaking waves solving the two-phase Navier-Stokes equations. We investigate the role of the Reynolds and Bond numbers on the energy, bubble and droplet statistics of strong plunging breakers, and explore the asymptotic regimes at high Reynolds and Bond numbers to be compared with laboratory breaking waves. Energetically, the breaking wave transitions from laminar to three-dimensional turbulent flow on a timescale that depends on the turbulent Reynolds number up to a limiting value of $Re_\lambda \sim 100$, consistent with the mixing transition observed in other canonical turbulent flows. We characterize the role of capillary effects on the impacting jet and ingested main cavity shape and subsequent fragmentation process. We confirm two regimes in the bubble size distribution, separated by the Hinze scale $r_H$. We extend the buoyant-energetic scaling of Deike et al. (2016) to account for the cavity shape and its scale separation from the Hinze scale. We show resolved bubbles up to one order of magnitude below the Hinze scale and observe a good collapse of the numerical data compared to laboratory breaking waves (Deane and Stokes 2002). We resolve droplet statistics at high Bond number and our data show good agreement with recent experiments (Erinin et al., 2009) in various statistics. We discuss velocity distributions for the droplets, finding ejection velocities up to four times the phase speed of the wave, which are produced during the most intense splashing events of the breaking process., Comment: 38 pages, 16 figures

Published

2021

4. A wall-modeled approach accounting for wave stress in Large Eddy Simulations of offshore wind farms

Author

A K Aiyer, L Deike, and M E Mueller

Subjects

History, Computer Science Applications, Education

Abstract

In the context of offshore wind farms, accurate predictions of surface fluxes in the marine atmospheric boundary layer are critical for Large Eddy Simulations (LES) of airflow over waves. The effect of the waves on the airflow is often modeled by prescribing the roughness length in the framework of Monin-Obukhov similarity theory. However, such approaches lack generalizability over different wave conditions due to reliance on model coefficients tuned to specific datasets. Wave phase-resolving simulations on the other hand have higher accuracy but also a higher computational cost. In this work, a sea surface-based hydrodynamic drag model is applied to model the pressure-based surface drag felt by the wind due to the waves. An offshore wind farm configuration is simulated using a wall-modeled LES, with the effect of the waves represented using the wave-drag model and the wind turbines represented by an actuator disk model. The approach is validated with data from high fidelity wave-resolving Large Eddy Simulations. The effect of the waves and the farm configuration on the mean velocity profiles power production, and kinetic energy budget are quantified.

Published

2022

5. The Study of the Human Head Abstractly Seen

Author

Clara L. Deike

Subjects

Human head, Anatomy, Psychology

Published

1937

6. Ocean emission of microplastic.

Author

Shaw DB, Li Q, Nunes JK, and Deike L

Abstract

Microplastics are globally ubiquitous in marine environments, and their concentration is expected to continue rising at significant rates as a result of human activity. They present a major ecological problem with well-documented environmental harm. Sea spray from bubble bursting can transport salt and biological material from the ocean into the atmosphere, and there is a need to quantify the amount of microplastic that can be emitted from the ocean by this mechanism. We present a mechanistic study of bursting bubbles transporting microplastics. We demonstrate and quantify that jet drops are efficient at emitting microplastics up to 280 μ m in diameter and are thus expected to dominate the emitted mass of microplastic. The results are integrated to provide a global microplastic emission model which depends on bubble scavenging and bursting physics; local wind and sea state; and oceanic microplastic concentration. We test multiple possible microplastic concentration maps to find annual emissions ranging from 0.02 to 7.4-with a best guess of 0.1-mega metric tons per year and demonstrate that while we significantly reduce the uncertainty associated with the bursting physics, the limited knowledge and measurements on the mass concentration and size distribution of microplastic at the ocean surface leaves large uncertainties on the amount of microplastic ejected., (© The Author(s) 2023. Published by Oxford University Press on behalf of National Academy of Sciences.)

Published

2023

7. Combatting Social Isolation, Anxiety, and Loneliness in Hospitalized Patients: A Quasi-Experimental Study.

Author

Keen A, Deike L, and Haan J

Subjects

Adult, Humans, Anxiety prevention & control, Loneliness, Social Isolation

Abstract

Objective: The objective of this study was to determine the effectiveness of an intervention related to social isolation and loneliness among hospitalized patients by improving: 1) social connectedness; 2) anxiety; and 3) loneliness and to evaluate experiences of the connection intervention., Background: Social isolation and loneliness can lead to detrimental effects on morbidity/mortality and health indices. A connection intervention was developed by investigators using key strategies to promote connectedness, providing in-person contact for hospitalized patients to meet individual and self-care needs., Methods: This quasi-experimental study was conducted in a Midwest adult academic health center. Social connectedness, anxiety, and loneliness were evaluated at baseline and postintervention using a paired-sample t test. Experience responses were analyzed using content analysis., Results: There were no significant differences in social connectedness, anxiety, or loneliness when comparing baseline with postintervention. Experience themes included sharing personal stories back and forth, treating me as a person, mitigating loneliness, and finding benefit., Conclusion: Despite nonsignificant findings, participants found benefit in filling the social void of being an inpatient. Clinicians should ensure that holistic care is delivered to hospitalized inpatients. Inclusive patient-centered strategies targeted to decrease social isolation and loneliness among acute care inpatients should continue to be developed and tested., Competing Interests: The authors declare no conflicts of interest., (Copyright © 2023 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2023

8. Bubbles spray aerosols: Certitudes and mysteries.

Author

Villermaux E, Wang X, and Deike L

Abstract

Ocean spray aerosol formed by bubble bursting are at the core of a broad range of atmospheric processes: they are efficient cloud condensation nuclei and carry a variety of chemical, biological, and biomass material from the surface of the ocean to the atmosphere. The origin and composition of these aerosols is sensibly controlled by the detailed fluid mechanics of bubble bursting. This perspective summarizes our present-day knowledge on how bursting bubbles at the surface of a liquid pool contribute to its fragmentation, namely to the formation of droplets stripped from the pool, and associated mechanisms. In particular, we describe bounds and yields for each distinct mechanism, and the way they are sensitive to the bubble production and environmental conditions. We also underline the consequences of each mechanism on some of the many air-sea interactions phenomena identified to date. Attention is specifically payed at delimiting the known from the unknown and the certitudes from the speculations., (© The Author(s) 2022. Published by Oxford University Press on behalf of the National Academy of Sciences.)

Published

2022

9. Bubble pinch-off in turbulence.

Author

Ruth DJ, Mostert W, Perrard S, and Deike L

Abstract

Although bubble pinch-off is an archetype of a dynamical system evolving toward a singularity, it has always been described in idealized theoretical and experimental conditions. Here, we consider bubble pinch-off in a turbulent flow representative of natural conditions in the presence of strong and random perturbations, combining laboratory experiments, numerical simulations, and theoretical modeling. We show that the turbulence sets the initial conditions for pinch-off, namely the initial bubble shape and flow field, but after the pinch-off starts, the turbulent time at the neck scale becomes much slower than the pinching dynamics: The turbulence freezes. We show that the average neck size, [Formula: see text], can be described by [Formula: see text], where [Formula: see text] is the pinch-off or singularity time and [Formula: see text], in close agreement with the axisymmetric theory with no initial flow. While frozen, the turbulence can influence the pinch-off through the initial conditions. Neck shape oscillations described by a quasi-2-dimensional (quasi-2D) linear perturbation model are observed as are persistent eccentricities of the neck, which are related to the complex flow field induced by the deformed bubble shape. When turbulent stresses are less able to be counteracted by surface tension, a 3-dimensional (3D) kink-like structure develops in the neck, causing [Formula: see text] to escape its self-similar decrease. We identify the geometric controlling parameter that governs the appearance of these kink-like interfacial structures, which drive the collapse out of the self-similar route, governing both the likelihood of escaping the self-similar process and the time and length scale at which it occurs., Competing Interests: The authors declare no competing interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

10. Bubble Bursting: Universal Cavity and Jet Profiles.

Author

Lai CY, Eggers J, and Deike L

Abstract

After a bubble bursts at a liquid surface, the collapse of the cavity generates capillary waves, which focus on the axis of symmetry to produce a jet. The cavity and jet dynamics are primarily controlled by a nondimensional number that compares capillary inertia and viscous forces, i.e., the Laplace number La=ργR_{0}/μ^{2}, where ρ, μ, γ, and R_{0} are the liquid density, viscosity, interfacial tension, and the initial bubble radius, respectively. In this Letter, we show that the time-dependent profiles of cavity collapse (tt_{0}) both obey a |t-t_{0}|^{2/3} inviscid scaling, which results from a balance between surface tension and inertia forces. Moreover, we present a scaling law, valid above a critical Laplace number, which reconciles the time-dependent scaling with the recent scaling theory that links the Laplace number to the final jet velocity and ejected droplet size. This leads to a self-similar formula which describes the history of the jetting process, from cavity collapse to droplet formation.

Published

2018

11. Experimental study of three-wave interactions among capillary-gravity surface waves.

Author

Haudin F, Cazaubiel A, Deike L, Jamin T, Falcon E, and Berhanu M

Abstract

In propagating wave systems, three- or four-wave resonant interactions constitute a classical nonlinear mechanism exchanging energy between the different scales. Here we investigate three-wave interactions for gravity-capillary surface waves in a closed laboratory tank. We generate two crossing wave trains and we study their interaction. Using two optical methods, a local one (laser doppler vibrometry) and a spatiotemporal one (diffusive light photography), a third wave of smaller amplitude is detected, verifying the three-wave resonance conditions in frequency and in wave number. Furthermore, by focusing on the stationary regime and by taking into account viscous dissipation, we directly estimate the growth rate of the resonant mode. The latter is then compared to the predictions of the weakly nonlinear triadic resonance interaction theory. The obtained results confirm qualitatively and extend previous experimental results obtained only for collinear wave trains. Finally, we discuss the relevance of three-wave interaction mechanisms in recent experiments studying gravity-capillary turbulence.

Published

2016

12. Capillary solitons on a levitated medium.

Author

Perrard S, Deike L, Duchêne C, and Pham CT

Subjects

Gravitation, Nonlinear Dynamics, Capillary Action, Hydrodynamics, Models, Theoretical, Water

Abstract

A water cylinder deposited on a heated channel levitates on its own generated vapor film owing to the Leidenfrost effect. This experimental setup permits the study of the one-dimensional propagation of surface waves in a free-to-move liquid system. We report the observation of gravity-capillary waves under a dramatic reduction of gravity (up to a factor 30), leading to capillary waves at the centimeter scale. The generated nonlinear structures propagate without deformation and undergo mutual collisions and reflections at the boundaries of the domain. They are identified as Korteweg-de Vries solitons with negative amplitude and subsonic velocity. The typical width and amplitude-dependent velocities are in excellent agreement with theoretical predictions based on a generalized Korteweg-de Vries equation adapted to any substrate geometry. When multiple solitons are present, they interact and form a soliton turbulencelike spectrum.

Published

2015

13. Direct numerical simulations of capillary wave turbulence.

Author

Deike L, Fuster D, Berhanu M, and Falcon E

Abstract

This work presents direct numerical simulations of capillary wave turbulence solving the full three-dimensional Navier-Stokes equations of a two-phase flow. When the interface is locally forced at large scales, a statistical stationary state appears after few forcing periods. Smaller wave scales are generated by nonlinear interactions, and the wave height spectrum is found to obey a power law in both wave number and frequency, in good agreement with weak turbulence theory. By estimation of the mean energy flux from the dissipated power, the Kolmogorov-Zakharov constant is evaluated and found to be compatible with the exact theoretical value. The time scale separation between linear, nonlinear interaction, and dissipative times is also observed. These numerical results confirm the validity of the weak turbulence approach to quantify out-of equilibrium wave statistics.

Published

2014

14. Energy flux measurement from the dissipated energy in capillary wave turbulence.

Author

Deike L, Berhanu M, and Falcon E

Abstract

We study experimentally the influence of dissipation on stationary capillary wave turbulence on the surface of a liquid by changing its viscosity. We observe that the frequency power-law scaling of the capillary spectrum departs significantly from its theoretical value when the dissipation is increased. The energy dissipated by capillary waves is also measured and found to increase nonlinearly with the mean power injected within the liquid. Here we propose an experimental estimation of the energy flux at every scale of the capillary cascade. The latter is found to be nonconstant through the scales. For fluids of low enough viscosity, we found that both capillary spectrum scalings with the frequency and the newly defined mean energy flux are in good agreement with wave turbulence theory. The Kolmogorov-Zakharov constant is then experimentally estimated and compared to its theoretical value.

Published

2014

15. Decay of capillary wave turbulence.

Author

Deike L, Berhanu M, and Falcon E

Subjects

Computer Simulation, Nonlinear Dynamics, Surface Properties, Capillary Action, Models, Chemical, Rheology methods, Solutions chemistry

Abstract

We report on the observation of freely decaying capillary wave turbulence on the surface of a fluid. The capillary wave turbulence spectrum decay is found to be self-similar in time with the same power law exponent as the one found in the stationary regime, in agreement with weak turbulence predictions. The amplitude of all Fourier modes are found to decrease exponentially with time at the same damping rate. The longest wavelengths involved in the system are shown to be damped by a viscous surface boundary layer. These long waves play the role of an energy source during the decay that sustains nonlinear interactions to keep capillary waves in a wave turbulent state.

Published

2012