45 research outputs found
Absolute and convective instabilities in non-local active-dissipative equations arising in the modelling of thin liquid films
This paper was presented at the 4th Micro and Nano Flows Conference (MNF2014), which was held at University College, London, UK. The conference was organised by Brunel University and supported by the Italian Union of Thermofluiddynamics, IPEM, the Process Intensification Network, the Institution of Mechanical Engineers, the Heat Transfer Society, HEXAG - the Heat Exchange Action Group, and the Energy Institute, ASME Press, LCN London Centre for Nanotechnology, UCL University College London, UCL Engineering, the International NanoScience Community, www.nanopaprika.eu.Absolute and convective instabilities in a non-local model that arises in the analysis of thin-film
flows over flat or corrugated walls in the presence of an applied electric field are discussed. Electrified liquid
films arise, for example, in coating processes where liquid films are deposited onto a target surfaces with a
view to producing an evenly coating layer. In practice, the target surface, or substrate, may be irregular in shape and feature corrugations or indentations. This may lead to non-uniformities in the thickness of the coating layer. Attempts to mitigate film-surface irregularities can be made using, for example, electric fields.
We analyse the stability of such thin-film flows and show that if the amplitude of the wall corrugations and/or the strength of the applied electric field is increased the convectively unstable flow undergoes a transition to an absolutely unstable flow
Deformation of a liquid film by an impinging gas jet: Modelling and experiments
© 2019, Avestia Publishing. We consider liquid in a cylindrical beaker and study the deformation of its surface under the influence of an impinging gas jet. Analyzing such a system not only is of fundamental theoretical interest, but also of industrial importance, e.g., in metallurgical applications. The solution of the full set of governing equations is computationally expensive. Therefore, to obtain initial insight into relevant regimes and timescales of the system, we first derive a reduced-order model (a thin-film equation) based on the long-wave assumption and on appropriate decoupling the gas problem from that for the liquid and taking into account a disjoining pressure. We also perform direct numerical simulations (DNS) of the full governing equations using two different approaches, the Computational Fluid Dynamics (CFD) package in COMSOL and the volume-of-fluid Gerris package. The DNS are used to validate the results for the thinfilm equation and also to investigate the regimes that are beyond the range of validity of this equation. We additionally compare the computational results with experiments and find good agreement
Absolute and convective instabilities in non-local active-dissipative equations arising in the modelling of thin liquid films
This paper was presented at the 4th Micro and Nano Flows Conference (MNF2014), which was held at University College, London, UK. The conference was organised by Brunel University and supported by the Italian Union of Thermofluiddynamics, IPEM, the Process Intensification Network, the Institution of Mechanical Engineers, the Heat Transfer Society, HEXAG - the Heat Exchange Action Group, and the Energy Institute, ASME Press, LCN London Centre for Nanotechnology, UCL University College London, UCL Engineering, the International NanoScience Community, www.nanopaprika.eu.Absolute and convective instabilities in a non-local model that arises in the analysis of thin-film
flows over flat or corrugated walls in the presence of an applied electric field are discussed. Electrified liquid
films arise, for example, in coating processes where liquid films are deposited onto a target surfaces with a
view to producing an evenly coating layer. In practice, the target surface, or substrate, may be irregular in
shape and feature corrugations or indentations. This may lead to non-uniformities in the thickness of the
coating layer. Attempts to mitigate film-surface irregularities can be made using, for example, electric fields.
We analyse the stability of such thin-film flows and show that if the amplitude of the wall corrugations
and/or the strength of the applied electric field is increased the convectively unstable flow undergoes a
transition to an absolutely unstable flow
Dynamic unbinding transitions and deposition patterns in dragged meniscus problems
This paper was presented at the 4th Micro and Nano Flows Conference (MNF2014), which was held at University College, London, UK. The conference was organised by Brunel University and supported by the Italian Union of Thermofluiddynamics, IPEM, the Process Intensification Network, the Institution of Mechanical Engineers, the Heat Transfer Society, HEXAG - the Heat Exchange Action Group, and the Energy Institute, ASME Press, LCN London Centre for Nanotechnology, UCL University College London, UCL Engineering, the International NanoScience Community, www.nanopaprika.eu.We sketch main results of our recent work on the transfer of a thin liquid film onto a flat plate
that is extracted from a bath of pure non-volatile liquid. Employing a long-wave hydrodynamic model, that
incorporates wettability via a Derjaguin (disjoining) pressure, we analyse steady-state meniscus profiles as the
plate velocity is changed. We identify four qualitatively different dynamic transitions between microscopic
and macroscopic coatings that are out-of-equilibrium equivalents of equilibrium unbinding transitions. The
conclusion briefly discusses how the gradient dynamics formulation of the problem allows one to systematically
extend the employed one-component model into thermodynamically consistent two-component models as used
to describe, e.g., the formation of line patterns during the Langmuir-Blodgett transfer of a surfactant layer
Additive noise effects in active nonlinear spatially extended systems
We examine the effects of pure additive noise on spatially extended systems
with quadratic nonlinearities. We develop a general multiscale theory for such
systems and apply it to the Kuramoto-Sivashinsky equation as a case study. We
first focus on a regime close to the instability onset (primary bifurcation),
where the system can be described by a single dominant mode. We show
analytically that the resulting noise in the equation describing the amplitude
of the dominant mode largely depends on the nature of the stochastic forcing.
For a highly degenerate noise, in the sense that it is acting on the first
stable mode only, the amplitude equation is dominated by a pure multiplicative
noise, which in turn induces the dominant mode to undergo several critical
state transitions and complex phenomena, including intermittency and
stabilisation, as the noise strength is increased. The intermittent behaviour
is characterised by a power-law probability density and the corresponding
critical exponent is calculated rigorously by making use of the first-passage
properties of the amplitude equation. On the other hand, when the noise is
acting on the whole subspace of stable modes, the multiplicative noise is
corrected by an additive-like term, with the eventual loss of any stabilised
state. We also show that the stochastic forcing has no effect on the dominant
mode dynamics when it is acting on the second stable mode. Finally, in a regime
which is relatively far from the instability onset, so that there are two
unstable modes, we observe numerically that when the noise is acting on the
first stable mode, both dominant modes show noise-induced complex phenomena
similar to the single-mode case
Dynamics of a thin film flowing down a heated wall with finite thermal diffusivity
Consider the dynamics of a thin film flowing down a heated substrate. The substrate heating generates a temperature distribution on the free surface, which in turn induces surface-tension gradients and corresponding thermocapillary stresses that affect the free surface and therefore the fluid flow. We study here the effect of finite substrate thermal diffusivity on the film dynamics. Linear stability analysis of the full Navier-Stokes and heat transport equations indicates if the substrate diffusivity is sufficiently small, the film becomes unstable at a finite wavelength and at a Reynolds number smaller than that predicted in the long-wavelength limit. This property is captured in a reduced-order system of equations derived using a weighted-residual integral-boundary-layer method. This reduced-order model is also used to compute the bifurcation diagrams of solution branches connecting the trivial flat film to traveling waves including solitary pulses. The effect of finite diffusivity is to separate a simultaneous Hopf-transcritical bifurcation into its individual component bifurcations. The appropriate Hopf bifurcation then connects only to the solution branch of negative-hump pulses, with wave speed less than the linear wave speed, while the branch of positive-single-hump pulses merges with the branch of positive-two-hump pulses at a supercritical Reynolds number. In the regime where finite-wavelength instability occurs, there exists a Hopf-bifurcation pair connected by a branch of periodic solutions, whose period cannot be increased indefinitely. Numerical simulation of the reduced-order system shows the development of a train of coherent structures, each of which resembles a stationary positive-hump pulse, and, in the regime of finite-wavelength instability, wavelength selection and saturation to periodic traveling waves
On the transition to dripping of an inverted liquid film
The transition to dripping in the gravity-driven flow of a liquid film under
an inclined plate is investigated at zero Reynolds number. Computations are
carried out on a periodic domain assuming either a fixed fluid volume or a
fixed flow rate for a hierarchy of models: two lubrication models with either
linearised curvature or full curvature (the LCM and FCM, respectively), and the
full equations of Stokes flow. Of particular interest is the breakdown of
travelling-wave solutions as the plate inclination angle is increased. For any
fixed volume the LCM reaches the horizontal state where it attains a
cosine-shaped profile. For sufficiently small volume, the FCM and Stokes
solutions attain a weak Young-Laplace equilibrium profile, the approach to
which is described by an asymptotic analysis generalising that of Kalliadasis &
Chang (1994) for the LCM. For large volumes, the bifurcation curves for the FCM
and Stokes model have a turning point so that the fully inverted state is never
reached. For fixed flow rate the LCM blows up at a critical angle that is well
predicted by asymptotic analysis. The bifurcation curve for the FCM either has
a turning point or else reaches a point at which the surface profile has an
infinite slope singularity, indicating the onset of multi-valuedness. The
latter is confirmed by the Stokes model which can be continued to obtain
overturning surface profiles. Overall the thin-film models either provide an
accurate prediction for dripping onset or else supply an upper bound on the
critical inclination angle
Noise induced state transitions, intermittency and universality in the noisy Kuramoto-Sivashinsky equation
We analyze the effect of pure additive noise on the long-time dynamics of the
noisy Kuramoto-Sivashinsky (KS) equation in a regime close to the instability
onset. We show that when the noise is highly degenerate, in the sense that it
acts only on the first stable mode, the solution of the KS equation undergoes
several transitions between different states, including a critical on-off
intermittent state that is eventually stabilized as the noise strength is
increased. Such noise-induced transitions can be completely characterized
through critical exponents, obtaining that both the KS and the noisy Burgers
equation belong to the same universality class. The results of our numerical
investigations are explained rigorously using multiscale techniques.Comment: 4 pages, 4 figure
Effect of driving on coarsening dynamics in phase-separating systems
We consider the Cahn-Hilliard (CH) equation with a Burgers-type convective
term that is used as a model of coarsening dynamics in laterally driven
phase-separating systems. In the absence of driving, it is known that solutions
to the standard CH equation are characterized by an initial stage of phase
separation into regions of one phase surrounded by the other phase (i.e.,
clusters or drops/holes or islands are obtained) followed by the coarsening
process, where the average size of the structures grows in time and their
number decreases. Moreover, two main coarsening modes have been identified in
the literature, namely, coarsening due to volume transfer and due to
translation. In the opposite limit of strong driving, the well-known
Kuramoto-Sivashinsky (KS) equation is recovered, which may produce complicated
chaotic spatio-temporal oscillations. The primary aim of the present work is to
perform a detailed and systematic investigation of the transitions in the
solutions of the convective CH (cCH) equation for a wide range of parameter
values, and, in particular, to understand in detail how the coarsening dynamics
is affected by an increase of the strength of the lateral driving force.
Considering symmetric two-drop states, we find that one of the coarsening modes
is stabilized at relatively weak driving, and the type of the remaining mode
may change as driving increases. Furthermore, there exist intervals in the
driving strength where coarsening is completely stabilized. In the intervals
where the symmetric two-drop states are unstable they can evolve, for example,
into one-drop states, two-drop states of broken symmetry or even time-periodic
two-drop states that consist of two traveling drops that periodically exchange
mass. We present detailed stability diagrams for symmetric two-drop states in
various parameter planes and corroborate our findings by selected time
simulations
Liquid Film Coating a Fiber as a Model System for the Formation of Bound States in Active Dispersive-Dissipative Nonlinear Media
We analyze the coherent-structure interaction and the formation of bound states in active dispersivedissipative
nonlinear media using a viscous film coating a vertical fiber as a prototype. The coherent
structures in this case are droplike pulses that dominate the evolution of the film.We study experimentally
the interaction dynamics and show evidence for formation of bound states. A theoretical explanation is
provided through a coherent-structures theory of a simple model for the flow