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    • 1241626
    • Noviembre 2015 - Octubre 2017
    EjecutadoGobierno Regional - GORE

    Waves are ubiquitous in nature. They are all around us in our daily lives, we find them in several contexts, in particular in fluids. They usually involve a complex variety of interaction processes, and di↵erent mechanisms. Of our particular inter- est is the case of waves at the interface between two fluids when they are perturbed. When strongly forced, the nonlinear interactions can produce a turbulent-like regime called wave turbulence. Theoretical, numerical and experimental studies have made a great deal of progress on this subject, and yet, there are several aspects that have not been properly addressed, namely the role of viscosity on the energy flux as it cascades through di↵erent scales or the physical origin of the intermittency phenomenon. In this proposal, we will consider the problem of capillary wave turbulence from an experimental and numerical point of view. One of the main complications to study surface wave turbulence is that, in the same system, there is involvement of di↵erent types of waves, such as the case of gravito-capillary wave turbulence. Thus, it becomes of foremost importance to study wave turbulence on the presence of only one type of waves. Thereby, in order to study pure capillary wave turbulence, gravity waves must be negligible. We propose to study a system of capillary surface waves at the interface of two immiscible and incompressible fluids, water and silicon oil, of almost equal densities and layer depths, thus preventing the action of gravity. By changing the kinematic viscosity ⌫, and density ⇢ of both fluids, it is possible to control the relation between injected and dissipated power, thus exploring several regimes in a simple and controlled way. We pose to implement the technique called Free-surface synthetic Schlieren that allows a reconstruction of the instantaneous surface topography. Velocity fields will be explored by using the standard Particle Image Velocimetry. We will make use of an already existing experimental setup which will be modified in order to accomplish these techniques adequately. With these measurements we will be able to compute the spectrum in frequency f and wavevector k, hence accessing to statistical and dynamical properties of capillary wave turbulence, such as intermittency, or the function of the injected power on the system. We also propose to use the open source solver GERRIS and make a systematic study on the role of viscosity on the cascading of the energy flux.
    Investigador/a Responsable
    • CP21-P134
    • Mayo 2015 - Agosto 2015
    EjecutadoMinisterio de Educación

    The Chilean Coastal Orographic Precipitation Experiment (CCOPE) was conducted during the austral winter of 2015 (May–August) in the Nahuelbuta Mountains (peak elevation 1.3 km MSL) of southern Chile (38ºS). CCOPE used soundings, two profiling Micro Rain Radars, a Parsivel disdrometer, and a rain gauge network to characterize warm and ice-initiated rain regimes and explore their consequences for orographic precipitation
    Co-Investigador/a
    • URO2395
    • Marzo 2015 - Octubre 2020
    En EjecuciónUniversidad de O'Higgins

    - Investigador asociado. Centro de Regulación del Genoma (CRG). Centro FONDAP FONDAP N°15090007, Director: Miguel Allende. Marzo 2015-actual.
    Co-Investigador/a
    • URO2395
    • Marzo 2015 - Diciembre 2018
    AdjudicadoUniversidad de O'Higgins

    Fondecyt Regular 2015- N°1151384. CONICYT. Proyecto titulado: Metal metabolism in soil bacterial communities from an extreme environment: A comparative genomics analysis. Instituciones patrocinantes: Universidad de Chile y Universidad de O’Higgins. Investigador responsable Dr. Mauricio González. Marzo 2014-Diciembre 2018.
    Co-Investigador/a
    • URO2395
    • Marzo 2015 - Octubre 2020
    En EjecuciónUniversidad de O'Higgins

    - Investigador asociado. Centro de Regulación del Genoma (CRG). Centro FONDAP FONDAP N°15090007, Director: Miguel Allende. Marzo 2015-actual.
    Co-Investigador/a
    • URO2395
    • Marzo 2015 - Diciembre 2018
    AdjudicadoUniversidad de O'Higgins

    Fondecyt Regular 2015- N°1151384. CONICYT. Proyecto titulado: Metal metabolism in soil bacterial communities from an extreme environment: A comparative genomics analysis. Instituciones patrocinantes: Universidad de Chile y Universidad de O’Higgins. Investigador responsable Dr. Mauricio González. Marzo 2014-Diciembre 2018.
    Co-Investigador/a
    • (INFRADEV-3- Ref: 676564)
    • Enero 2015 - Diciembre 2019
    FinalizadoAgencia Nacional de Investigación y Desarrollo - ANID

    EPOS, the European Plate Observing System, is a multidisciplinary, distributed research infrastructure that facilitates integrating data, data products, and facilities from the solid Earth science community in Europe. Participación como miembro del equipo investigador.
    Co-Investigador/a
    • 1241626
    • Noviembre 2014 - Septiembre 2015
    EjecutadoGobierno Regional - GORE

    Position that involved teaching an undergraduate course to students from ENS along with research on an experimental study of wave turbulence.
    Investigador/a Responsable
    • FONDEF IT23I0012
    • Noviembre 2014 - Octubre 2017
    EjecutadoAgencia Nacional de Investigación y Desarrollo - ANID

    Variational Problems Under Conic Constraints

    Co-Investigador/a
    • ID: 950106 Resolución: 5457-2023
    • Julio 2014 - Junio 2016
    EjecutadoGobierno Regional - GORE

    Analytical and Numerical Solutions of Two-Phase Flow-Induced Vibration Phenomenon in Pipes

    Co-Investigador/a