Mención Internacional en el título de doctorFluid-fluid interfaces are ubiquitous in nature and everyday life, where they are found across scales and
material properties, as for instance in many engineering, biological, and physiological applications
and processes. In particular, cylindrical interfaces and, in general, the spontaneous tendency of
surface-tension-driven flows to break up into drops, have fascinated naturalists and scientists throughout
history; a fascination that lasts to date due to its crucial relevance in many phenomena of fundamental and
applied interest. This is the reason for the huge research effort devoted to understand the behavior and
dynamics of these filaments, namely elongated vesicles and membranes which are frequent in biological
environments, or liquid jets that are routinely used for additive manufacturing applications. In most
of these scenarios, the interface is usually populated with surface-active molecules, macromolecules,
proteins, or contaminated with particles, which eventually form a complex microstructure that endows
the interface with a rheologically complex behavior. The interaction between this structure and the
hydrodynamic forces is traduced macroscopically into nonlinear interfacial rheological properties and
nontrivial constitutive equations relating the surface stress with the deformation of the surface. An
interface that possesses these kinds of properties is usually referred to as a complex interface, and
the particular field of study is typically denoted by interfacial rheology. Nonetheless, despite of this
complexity, these material cylinders share the same intrinsic instability induced by the interfacial tension
known as the Plateau-Rayleigh instability, where disturbances of sufficiently long wavelength trigger the
instability by decreasing the surface energy at constant volume.
The complex interactions between the bulk fluids and the surface layer complicate the theoretical
modelling and the experimental protocols and measurements of the material properties associated with
the interface. A vast number of issues regarding the behavior and dynamics of such complex fluid
threads are yet not understood. In particular, this thesis aims to unravel fundamental aspects of the linear
and nonlinear dynamics of liquid filaments whose interface is endowed with complex surface rheology,
which can be elastic and/or viscous. We first deduce the components of the surface stress balance
modified by interfacial elastic and viscous forces, which is necessary for the derivation of leading-order
and second-order one-dimensional models. The performance of these approximations is then evaluated
in the linear regime by comparing their associated growth rate of small perturbations with the one
obtained from the complete conservation equations. To this end, we use Rayleigh’s temporal linear
stability analysis to deduce the corresponding dispersion relation of a liquid filament with interfacial
rheology. Additionally, by performing simulations of the full conservation equations, we then investigate
the nonlinear dynamics of these complex filaments. In particular we study the effect of Marangoni and
surface viscous stresses on the natural breakup and thinning of threads, and the subsequent formation of
satellite droplets. Finally, we study the linear and nonlinear dynamics of a capillary jet injected in the
direction of gravity and confined between the nozzle and a bath of the same fluid.This doctoral dissertation was supported by Ministerio de Educación, Cultura, y Deporte
through the fellowship FPU16/02562, and its associated program Ayudas a la Movilidad 2017
and 2018 during my stays with the group of Prof. Benoit Scheid (TIPs) at the University of
Brussels, and with the group of Prof. Howard A. Stone at Princeton University.
This work also had financial support by Ministerio de Economía y Competitividad,
Subdirección General de Gestión de Ayudas a la Investigación, under the projects
DPI2014-59292-C3-1-P, DPI2014-59292-C3-3-P, DPI2015-71901-REDT, and by Ministerio
de Ciencia, Innovación y Universidades-Agencia Estatal de Investigación through the project
DPI2017-88201-C3-3-R, partly financed through FEDER European funds. Support from
the Red Nacional para el Desarrollo de la Microfluídica, RED2018-102829-T, is also
acknowledged.Programa de Doctorado en Mecánica de Fluidos por la Universidad Carlos III de Madrid, la Universidad de Jaén, la Universidad de Zaragoza, la Universidad Nacional de Educación a Distancia, la Universidad Politécnica de Madrid y la Universidad Rovira i VirgiliPresidente: Jens Eggers,.- Secretario: Nicolas Bremond.- Vocal: José M. Gordillo Arias de Saavedr
