Objectives and Content
Objectives:
The course aims to present advanced topics of the large-scale and mesoscale ocean circulation, based on the governing equations in geophysical fluid dynamics.
Contents:
With reference to the quasi-geostrophic equations as mathematical platform, the course covers Rossby waves, barotropic - and baroclinic instability, the large-scale circulation with theories of wind-driven flows in mid- and high-latitude ocean as Sverdrup- and Stommel theory, and stratification effects like upwelling and down welling. Simple theories of the buoyancy-driven large-scale circulation as well as dynamic modes and eddyinduced advection, will be covered.
Prerrequisitos
Resultados del aprendizaje
On completion of the course the student should have the following learning outcomes defined in terms of knowledge, skills and general competence:
Knowledge
The student
- has a good understanding of the basic principles of large scale motion on a rotating planet
- understand the governing equations on various phenomena in geophysical fluid dynamics
- understand the quasi-geostrophic dynamics
- understand classical instability theories
- understand the large scale wind driven ocean dynamics and classical theories
Skills
The student
- is able to derive the quasi-geostrophic equations, and discuss barotropic and baroclinic Rossby wave solutions
- is able to derive various solutions for the wind-driven ocean circulation, including upwelling and downwelling
- is able to discuss simplified models of the buoyancy-driven ocean circulation
- is able to derive and discuss QG integral constraints for barotropic and baroclinic instability
General competence
The student
- can discuss basic governing equation in dynamical oceanography
- can derive, scale and simplify the governing equations
- can solve dynamical problems in the ocean
- can present and discuss advanced topics in meso- and large scale dynamical oceanography
Archivos/Documentos
Categorías CINE (ISCED)
