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Deep Learning Atmospheric Models Reliably Simulate Out-of-Sample Land Heat and Cold Wave Frequencies

generative-ai › diffusion

📄 Abstract

Abstract: Deep learning (DL)-based general circulation models (GCMs) are emerging as fast simulators, yet their ability to replicate extreme events outside their training range remains unknown. Here, we evaluate two such models -- the hybrid Neural General Circulation Model (NGCM) and purely data-driven Deep Learning Earth System Model (DL\textit{ESy}M) -- against a conventional high-resolution land-atmosphere model (HiRAM) in simulating land heatwaves and coldwaves. All models are forced with observed sea surface temperatures and sea ice over 1900-2020, focusing on the out-of-sample early-20th-century period (1900-1960). Both DL models generalize successfully to unseen climate conditions, broadly reproducing the frequency and spatial patterns of heatwave and cold wave events during 1900-1960 with skill comparable to HiRAM. An exception is over portions of North Asia and North America, where all models perform poorly during 1940-1960. Due to excessive temperature autocorrelation, DL\textit{ESy}M tends to overestimate heatwave and cold wave frequencies, whereas the physics-DL hybrid NGCM exhibits persistence more similar to HiRAM.

Authors (4)

Zilu Meng

Gregory J. Hakim

Wenchang Yang

Gabriel A. Vecchi

Submitted

July 3, 2025

arXiv Category

physics.ao-ph

arXiv PDF

Key Contributions

Evaluates two DL-based GCMs (NGCM and DLESyM) against a conventional model (HiRAM) in simulating land heatwaves and cold waves. Demonstrates that both DL models generalize successfully to unseen climate conditions, broadly reproducing extreme event frequencies and patterns.

Business Value

Accelerates climate simulations, enabling faster research and potentially more accurate predictions of extreme weather events, which is vital for disaster preparedness, infrastructure planning, and policy making.

Paper Metadata

Innovation Type

Evaluation and Validation

Deployment Feasibility

High for simulation purposes. The speed advantage of DL models makes them attractive for large-scale climate studies.

Limitations Addressed

Uncertainty about the ability of DL-based GCMs to replicate extreme events outside their training range (out-of-sample performance).

Performance Gains

DL models generalize successfully to unseen climate conditions with skill comparable to a high-resolution conventional model.

Technical Tags

Deep Learning (DL)General Circulation Models (GCMs)Atmospheric ModelsExtreme EventsLand HeatwavesCold WavesOut-of-Sample SimulationGeneralizationNeural General Circulation Model (NGCM)Deep Learning Earth System Model (DLESyM)

Research Topics

Climate ModelingDeep LearningScientific SimulationExtreme Weather EventsModel Generalization

Methods & Architectures

Deep Learning (DL) based GCMsHybrid Neural GCM (NGCM)Data-driven DL Earth System Model (DLESyM) Neural General Circulation Model (NGCM)Deep Learning Earth System Model (DLESyM)

Applications & Tasks

Climate Science Meteorology Environmental Science Climate SimulationExtreme Event PredictionModel Generalization Simulating land heatwaves and cold wavesEvaluating DL-based GCMs' ability to replicate extreme events out-of-sample

Datasets & Benchmarks

Datasets

Observed sea surface temperatures, Sea ice data

Benchmarks

Comparable skill to HiRAM in reproducing frequency and spatial patterns of heatwave and cold wave events during 1900-1960.

Frequency of heatwaves/cold wavesSpatial patterns of eventsTemperature autocorrelation

Related Fields

Climate ScienceMeteorologyComputational Fluid DynamicsMachine LearningScientific Computing

Keywords

Deep LearningClimate ModelsGCMExtreme EventsHeatwavesCold WavesOut-of-SampleGeneralizationNGCMDLESyMAtmospheric ScienceSimulation

Academic Context

#Climate Modeling#Deep Learning#Scientific Simulation#Extreme Weather Events#Model Generalization

Technology Stack

Frameworks & Libraries

Deep Learning

Commercial Potential

Potential Products

Faster climate simulation softwareTools for predicting extreme weather eventsAI-driven climate analysis platforms

Target Industries

Climate ResearchMeteorology ServicesInsuranceAgricultureUrban Planning

Use Case Examples

Rapidly simulating future climate scenarios to assess risks.Improving the accuracy and lead time of extreme weather forecasts.Analyzing the impact of climate change on specific regions.

Competitive Edge

Demonstrates the viability and effectiveness of DL-based GCMs as fast simulators that can generalize well to unseen climate conditions, offering a potential acceleration over traditional GCMs.

Market Opportunity

Significant, related to climate services, risk assessment, and policy support.

Revenue Models

Licensing of simulation softwaredata analysis services.

Resource Requirements

Compute Needs

High, for training and running DL-based GCMs, but potentially faster inference than traditional GCMs.

Data Requirements

Historical climate data (SST, sea ice), forcing data.

Deployment Constraints

Need for large-scale computing infrastructure.,Validation against physical principles.,Potential for model-specific biases (e.g., excessive temperature autocorrelation).

Scalability

DL models can be computationally intensive but offer faster simulation times once trained.

Production Readiness

Maturity Level

Research/Validation

Time to Market

Long, for operational climate prediction systems.

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