Sentences with phrase «circulation model development»

As quoted yesterday about Jastrow in David Randall's book General Circulation Model Development, Hansen writes

This model hinges on the development of publishing systems that incorporate networked forms of production and circulation.

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.»

The meeting will mainly cover the following themes, but can include other topics related to understanding and modelling the atmosphere: ● Surface drag and momentum transport: orographic drag, convective momentum transport ● Processes relevant for polar prediction: stable boundary layers, mixed - phase clouds ● Shallow and deep convection: stochasticity, scale - awareness, organization, grey zone issues ● Clouds and circulation feedbacks: boundary - layer clouds, CFMIP, cirrus ● Microphysics and aerosol - cloud interactions: microphysical observations, parameterization, process studies on aerosol - cloud interactions ● Radiation: circulation coupling; interaction between radiation and clouds ● Land - atmosphere interactions: Role of land processes (snow, soil moisture, soil temperature, and vegetation) in sub-seasonal to seasonal (S2S) prediction ● Physics - dynamics coupling: numerical methods, scale - separation and grey - zone, thermodynamic consistency ● Next generation model development: the challenge of exascale, dynamical core developments, regional refinement, super-parametrization ● High Impact and Extreme Weather: role of convective scale models; ensembles; relevant challenges for model development

Both procedures have UNKNOWN impact on topology of solutions of the original Navier - Stokes problem, especially on long term evolution (which is precisely the entire goal of climate modeling), on development of «coherent structures» and their interaction and formation of seemingly stable large - scale atmospheric circulation.

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).

The Working Group on Numerical Experimentation (WGNE), jointly established by the WCRP Joint Scientific Committee (WCRP - JSC) and the WMO Commission for Atmospheric Sciences (CAS), which is responsible for WWRP and GAW, has the responsibility of fostering the development of atmospheric circulation models for use in weather, climate, water and environmental prediction on all time scales and diagnosing and resolving shortcomings (WMO / TD 121).

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.