Expert-level meteorology covering atmospheric dynamics, thermodynamics, synoptic meteorology, mesoscale systems, numerical weather prediction, and climate dynamics.
Troposphere: weather occurs here, temperature decreases with height, 0-12 km. Stratosphere: temperature increases with height, ozone layer, 12-50 km. Tropopause: boundary between troposphere and stratosphere. Standard atmosphere: reference profile of temperature, pressure, density vs altitude.
Dry adiabatic lapse rate: 9.8 K/km for unsaturated air. Moist adiabatic lapse rate: 4-7 K/km for saturated air. CAPE: convective available potential energy — thunderstorm intensity indicator. Skew-T diagram: thermodynamic diagram for atmospheric sounding analysis. Lifting condensation level: altitude where air parcel reaches saturation.
Geostrophic wind: balance between pressure gradient and Coriolis force. Thermal wind: vertical wind shear related to horizontal temperature gradient. Vorticity: rotation of air parcels, positive cyclonic in Northern Hemisphere. Jet stream: fast upper-level winds guiding surface weather systems.
Fronts: boundaries between air masses — cold, warm, occluded, stationary. Cyclones: low pressure systems, convergence at surface, rising air, clouds. Anticyclones: high pressure, divergence, sinking air, clear skies. Norwegian cyclone model: development and occlusion of mid-latitude cyclones.
Primitive equations: Navier-Stokes + thermodynamics + continuity. Grid models: finite difference or spectral, GFS, ECMWF. Ensemble forecasting: multiple runs with perturbed initial conditions. Data assimilation: 4D-Var, EnKF — merge observations into model state.
| Pitfall | Fix |
|---|---|
| Over-relying on single model | Always compare multiple NWP products |
| Ignoring mesoscale effects | NWP coarse resolution misses local terrain effects |
| CAPE without shear context | High CAPE needs wind shear for severe weather |
| Forgetting Coriolis in dynamics | Essential for large-scale flow patterns |