As quoted yesterday about Jastrow in David Randall's book
General Circulation Model Development, Hansen writes
Not exact matches
Future
development of the ozone layer calculated by a
general circulation model with fully interactive chemistry.
Development of
models for the
general circulation of the ocean started later, but has proceeded in a similar manner.
«Progress and Future
Developments in
Modelling the Climate System with
General Circulation Models.»
Syllabus: Lecture 1: Introduction to Global Atmospheric
Modelling Lecture 2: Types of Atmospheric and Climate
Models Lecture 3: Energy Balance
Models Lecture 4: 1D Radiative - Convective
Models Lecture 5:
General Circulation Models (GCMs) Lecture 6: Atmospheric Radiation Budget Lecture 7: Dynamics of the Atmosphere Lecture 8: Parametrizations of Subgrid - Scale Physical Processes Lecture 9: Chemistry of the Atmosphere Lecture 10: Basic Methods of Solving
Model Equations Lecture 11: Coupled Chemistry - Climate
Models (CCMs) Lecture 12: Applications of CCMs: Recent
developments of atmospheric dynamics and chemistry Lecture 13: Applications of CCMs: Future Polar Ozone Lecture 14: Applications of CCMs: Impact of Transport Emissions Lecture 15: Towards an Earth System
Model
«
Development of Global Coupled Ocean - Atmosphere
General Circulation Models.»
NASA's Goddard Institute for Space Studies (GISS) has a long history in climate studies, which led to the
development of one of the most accurate and complete
models of Earth's global climate, the
General Circulation Model (GCM).
GEOG 5100: Climate System
Modeling This is a hands on research seminar focusing on climate
model development from the simplest to most complex
models culminating with a final research project designing and analyzing a
General Circulation climate
model experiment.