Physics of the atmosphere

The Earth's atmosphere: vertical structure and characteristics; chemical composition, trace gases, greenhouse effect and the climate system.
Atmospheric thermodynamics: ideal gas law for dry and moist air, water vapour in the atmosphere, hydrostatic equation, geopotential, hypsometric equation and its applications, first principle of thermodynamics applied to the atmosphere, adiabatic processes, potential temperature, static stability for dry and moist atmosphere, thermodynamic diagrams and meteorological applications; second law of thermodynamics, Clausius-Clapeyron equation. Formation and classification of clouds and precipitation.
Overview of the networks for meteorological observations, measurements and analysis charts.
Atmospheric dynamics: basic concepts of atmospheric fluid dynamics, eulerian and lagrangian approach; forces, equation of motion in a rotating system, scale analysis and solution of simplified equations: geostrophic, inertial, cyclostrofic and gradient flows. Large scale motion: ageostrophic wind and vertical motion, cyclonic and anticyclonic circulation and meteorological charts. Barotropic/baroclinic atmosphere and thermal wind.
Radiative processes: electromagnetic spectrum, black body radiation, radiation balance for the sun-earth-atmosphere system; short and long wave radiation, interaction of the Earth atmosphere with the radiation, radiation balance at the earth surface and at the top of the atmosphere. Greenhouse effect. Radiative transfer equations. Radiative-convective equilibrium.
Introduction to the general circulation of the atmosphere.
Overview of numerical weather prediction models.