Climate Modeling

Climate Modeling for the future of the planet

Since the early days of climate modeling, software, hardware, and the way that engineers and scientists collaborate have gone through incredible transformations. Better data and technologies will inform how we mitigate and adapt to global impacts, such as sea level rise, community destruction, and biodiversity loss.

Two pictures of the earth. One with the words 'Satellite Image' and one with the word 'Climate Model'

What are climate models?

Planetary-scale Earth simulations known as global climate model projections are the primary sources of information on future climate change.

Climate models are based on mathematical equations represented using a grid mesh that covers the globe: a finer grid mesh is more accurate but much more computationally expensive. Current global climate projections agree that a world with more greenhouse gases will be warmer everywhere, especially over land and at high latitudes. However, the current understanding of high-risk outcomes like rainfall extremes are more uncertain, and these changes have the potential to impact billions of people.

Faster Climate Models

Since the early days of climate modeling inception, software, hardware, and the way that engineers and scientists collaborate have gone through incredible transformations. We are redesigning a climate model that will run on the world’s largest supercomputers. A new programming language specifically designed for climate modeling helps scientists work more efficiently, allowing fine-grid weather and climate models to run up to tenfold faster and longer.

Computer servers lit up with green and red lights.

Two images of a cumulonimbus cloud -- one is high resolution and the other is a pixelated version

Better Climate Models

In the same way photos have become clearer because screens now pack in more pixels, high resolution climate models now provide a detailed and actionable view of our world. High resolution models are very costly to run, but they can be leveraged to increase the accuracy of currently affordable models by replacing their less accurate components with machine learning (ML) -- something that has never been done in operational climate models before.

Smarter, More Accurate Simulations with Machine Learning

The technology behind climate models was first created 50 years ago. Much has changed in technology since then, and there is now opportunity to make use of the latest advances in supercomputing, modern programming languages, and machine learning to improve climate models. We're building modern machine learning into current climate models to improve their performance in key areas and ultimately to refine climate change predictions. Our goal is to accelerate climate science by building models that exploit the world’s fastest supercomputers, modern programming languages, and coding best practices.

A satellite image of earth with swirly white clouds

A conference room with a bunch of folks having a meeting

Create Open-Source and Collaborative Solutions

We're developing open-source software so the broader climate modeling community can easily adopt our advances. We partner with a leading climate modeling center, NOAA’s Geophysical Fluid Dynamics Laboratory, to ensure our work builds on their valuable experience and has the quickest impact. Our work is focused on improving their experimental fine-grid model, SHiELD, which shares components with the U. S. global weather forecasting model. This collaboration brings our team’s innovation together with GFDL’s climate modeling experience and computing resources to achieve quicker impact that can set an example for other climate modeling centers to follow.

Learn more about NOAA’s Geophysical Fluid Dynamics Laboratory

Recent Updates

Are global storm resolving models good for simulating cirrus clouds?
April 20, 2022
This paper and a companion by Turbeville et al. were NSF-sponsored collaborations between Bretherton and co-workers at the University of Washington…
Glaciation of supercooled cumulus clouds by rime splintering affects Southern Ocean albedo in a GSRM
April 20, 2022
This paper was an NSF-sponsored collaboration between Bretherton and co-workers at the University of Washington and Stony Brook University. Five-day…
Bretherton et al. 2022 paper chosen as AGU Editor's Highlight in Eos
March 15, 2022
Our recent corrective ML paper was selected as an AGU Editor's Highlight in Eos, their weekly newsletter. Only 2% of all AGU publications are so…
Read our new paper on corrective ML to improve climate models using fine-grid reference models
January 22, 2022
The Climate Modeling ML group's first paper applying corrective machine learning to make a computationally efficient coarse-grid global climate model…

Recent Papers

View All Climate Modeling Papers

Hallett‐Mossop Rime Splintering Dims Cumulus Clouds Over the Southern Ocean: New Insight From Nudged Global Storm‐Resolving Simulations
R. Atlas, C. Bretherton, M. Khairoutdinov, P. BlosseyAGU Advances • 2022
American Geophysical Union Editor Highlight
In clouds containing both liquid and ice with temperatures between −3°C and −8°C, liquid droplets collide with large ice crystals, freeze, and shatter, producing a plethora of small ice splinters. This process, known as Hallett‐Mossop rime splintering, and…
Correcting Coarse-Grid Weather and Climate Models by Machine Learning From Global Storm-Resolving Simulations
Bretherton, C. S., B. Henn, A. Kwa, N. D. Brenowitz, O. Watt-Meyer, J. McGibbon, W. A. Perkins, S. K. Clark, and L. HarrisJournal of Advances in Modeling Earth Systems • 2022
American Geophysical Union Editor Highlight
Global atmospheric `storm-resolving' models with horizontal grid spacing of less than 5~km resolve deep cumulus convection and flow in complex terrain. They promise to be reference models that could be used to improve computationally affordable coarse-grid…
Tropical Cirrus in Global Storm‐Resolving Models: 2. Cirrus Life Cycle and Top‐of‐Atmosphere Radiative Fluxes
S. M. Turbeville, J. M. Nugent, T. Ackerman, C. Bretherton, P. BlosseyEarth and Space Science • 2021 Cirrus clouds of various thicknesses and radiative characteristics extend over much of the tropics, especially around deep convection. They are difficult to observe due to their high altitude and sometimes small optical depths. They are also difficult to…
Tropical Cirrus in Global Storm‐Resolving Models: 1. Role of Deep Convection
J. Nugent, S. M. Turbeville, C. Bretherton, P. Blossey, T. AckermanEarth and Space Science • 2021 Pervasive cirrus clouds in the upper troposphere and tropical tropopause layer (TTL) influence the climate by altering the top‐of‐atmosphere radiation balance and stratospheric water vapor budget. These cirrus are often associated with deep convection, which…
Domain-Specific Multi-Level IR Rewriting for GPU: The Open Earth Comp
Gysi, T., C. Müller, T. Grosser, T. Hoefler, O. Zinenko, O. Fuhrer, E. Davis, and T. WickyACM Transactions on Architecture and Code Optimization • 2021 Most compilers have a single core intermediate representation (IR) (e.g., LLVM) sometimes complemented with vaguely defined IR-like data structures. This IR is commonly low-level and close to machine instructions. As a result, optimizations relying on domain…