IMPRS-gBGC course: Atmosphere & Ocean
 

• Overview of the module: goals, expectations
• Introduction to the climate system: atmosphere, ocean, land, ice, interior, structure, composition, global biogeochemical cycles, human activity and global change
• Atmospheric basics: forms of energy and energy transfer, first and second law of thermodynamics, ideal gas law, hydrostatic balance, lapse rate, barometric equation, Carnot efficiency, maximum work

• Radiative forcing: basic radiation laws, radiative temperature, variations in solar radiation, greenhouse effect
• Planetary energy balance: components of the global energy balance, atmospheric heat transport, planetary comparison
• Biogeochemical cycles: global cycles, residence times, geology and biogeochemical cycles, evolution of atmospheric composition
• Wrap-up: summary, next steps, feedback

• black body radiation and the electromagnetic spectrum
• molecular absorption lines of major constituents of the atmosphere
• absorption coefficient and opacity
• continuous and discrete radiative transfer equation
• solar and earth spectra at the ground and the top of the atmosphere
• excercise on radiative transfer calculations

• scattering in the Rayleigh, Mie, and geometric regimes
• introduction to aerosols and their optical properties
• direct and indirect radiative effects of aerosols
• cloud radiative properties
• multiple scattering

Using an online version of a real one-dimensional radiative transfer model, various experiments will be undertaken. This will allow one to test the effect of changing the quantity of various greenhouse gases, the aerosol optical depth, the cloud properties, and the surface albedo, among other things. It should provide the doctoral researchers with a better feeling of what 1 W/m² means.

• global circulation of the atmosphere
• frontal systems
• basics of global ocean circulation
• hydrologic cycle, clouds

• Meteorological observation systems
• Meteorological data assimilation
• Reanalysis, reanalysis products
• Atmospheric tracer transport
• Application: Atmospheric inversion

We will use a Lagrangian Dispersion Model (LPDM) and a global Transport Model to see how atmospheric transport and mixing of emissions and biosheric fluxes affects the distribution of CO₂ in the atmosphere.

• fluxes at the land surface
• albedo climate feedback
• biophysical feedback

• general characteristics, structure and diurnal cycle
• atmospheric stability

• atmospheric turbulence
• scaling laws

• turbulent fluxes
• eddy covariance method
• measurement technique

• demonstration of eddy covariance measurement system at the institute
• processing of eddy covariance data

• anthropogenic and natural drivers
• impact on radiative forcing
• detection and attribution of climate change
• climate projections for this century
• long term (millenia) climate change
• mitigation
• geoengineering