The first global numerical simulations of the atmosphere — defining the basic structure of the numerical weather prediction and climate models that are still in use today throughout the world.
The first numerical simulation of the world ocean.
The initial definition and further elaborations of many of the central issues in global warming research, including water vapor feedback, polar amplification of temperature change, summer mid-continental dryness and cloud feedback.
The first coupled atmosphere-ocean climate models and the first simulations of global warming using these models.
The development of a state-of-art hurricane model and its transfer to operations in the NOAA National Weather Service and the Navy.
Scientific Divisions
The GFDL has a diverse community of about 300 researchers, collaborators and staff, with many from Britain, India, China, Japan, France, etc. The laboratory is currently organized into several scientific divisions, in addition to a large group of scientific programmers known as the Modeling Systems Division, as well as a large computer support group.
Atmospheric Physics
Current head: Dr. Venkatachalam Ramaswamy This divisions goal is to employ numerical models and observations of the Earth System to characterize and quantify atmospheric physical processes, particularly those involving greenhouse gases, aerosols, water vapor, and clouds, and their roles in atmospheric general circulation, weather and climate.
Biogeochemistry, Atmospheric Chemistry, and Ecosystems
Current head: Dr. John P. Dunne This divisions goal is to develop and use the GFDL’s earth system models to create a more comprehensive understanding of the interactions between physical, chemical, and ecological drivers and feedbacks on the earth system.
Ocean and Cryosphere
Current head: Dr. Rong Zhang This divisions goal is to conduct leading research to understand ocean and cryosphere changes and variability; their interactions with weather, climate, sea level, and ecosystems; and advance prediction and projection of future changes. To support this goal, we are developing state-of-the-science numerical models for the ocean, sea ice, land ice, and fully coupled models.
Seasonal-to-Decadal Variability and Predictability
Current head: Dr. Tom Delworth This divisions goal is to improve our understanding of climate variability, predictability and change on time scales ranging from seasonal to multidecadal. This includes internal variability of the coupled climate system, and the response to changing radiative forcing. We are actively working to develop a next-generation experimental seasonal-to-decadal prediction system.
Current head: Thomas Knutson This divisions goal is to develop innovative physical and dynamical components for the next generation of earth system models, with special emphasis on high resolution atmospheric model development. We aim to explore the frontiers of weather and climate modeling and analysis, and to improve the predictions of high-impact events such as hurricanes, floods, severe storms, and droughts, from weather to seasonal and interannual time-scales.
Facilities
The GFDL is located at Princeton University's Forrestal Campus in Princeton, NJ. Since March 2011, the GFDL no longer possesses an on-site supercomputer. They instead utilize a massively parallelCray supercomputer with over 140,000 processor cores which is currently located at Oak Ridge National Laboratory in Oak Ridge, Tennessee. This contrasts from their previous systems architecture, which consisted of eight Silicon GraphicsAltix computers, each housing 1024 processor cores. Hardware updates occur on average, every 18 months. The GFDL has been using high-performance computing systems to perform numerical modeling since the 1950s.
