Climate change is arguably the greatest threat facing humanity today.
Accurately predicting climate change is critical to plan for its disastrous impacts well in advance and to adapt to sea level rise, ecosystem shifts, and food and water security needs.
The Fourier Neural Operator (FNO) -- a novel AI model -- learns complex physical systems accurately and efficiently.
Here we see the FNO emulate a high-resolution Earth dataset, ERA5, and predict the behavior of extreme weather events across the globe days in advance in just 0.25 seconds on NVIDIA GPUs.
At 100,000 times faster than traditional numerical weather models, this is a significant step towards building digital twin Earth.
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The earth is warming.
The past seven years are on track to be the seven warmest on record.
The emissions of greenhouse gases from human activities are responsible for approximately 1.1°C of average warming since the period 1850-1900.
What we’re experiencing is very different from the global average.
What we’re experiencing is very different from the global average.
We experience extreme weather — historic droughts, unprecedented heatwaves, intense hurricanes, violent storms and catastrophic floods.
Climate disasters are the new norm.
We need to confront climate change now.
Yet, we won’t feel the impact of our efforts for decades.
It’s hard to mobilize action for something so far in the future. But we must know our future today — see it and feel it — so we can act with urgency.
To make our future a reality today, simulation is the answer.
To make our future a reality today, simulation is the answer.
"The hardware needed to “see” just how bad it’s gonna be." @AnthonyDiMare
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To develop the best strategies for mitigation and adaptation, we need climate models that can predict the climate in different regions of the globe over decades.
Unlike predicting the weather, which primarily models atmospheric physics, climate models are multidecade simulations that model the physics, chemistry and biology of the atmosphere, waters, ice, land and human activities.
Climate simulations are configured today at 10- to 100-kilometer resolutions.
But greater resolution is needed to model changes in the global water cycle — water movement from the ocean, sea ice, land surface and groundwater through the atmosphere and clouds.
Unlike predicting the weather, which primarily models atmospheric physics, climate models are multidecade simulations that model the physics, chemistry and biology of the atmosphere, waters, ice, land and human activities.
Climate simulations are configured today at 10- to 100-kilometer resolutions.
But greater resolution is needed to model changes in the global water cycle — water movement from the ocean, sea ice, land surface and groundwater through the atmosphere and clouds.
Changes in this system lead to intensifying storms and droughts.
Meter-scale resolution is needed to simulate clouds that reflect sunlight back to space.
Meter-scale resolution is needed to simulate clouds that reflect sunlight back to space.
Scientists estimate that these resolutions will demand millions to billions of times more computing power than what’s currently available.
It would take decades to achieve that through the ordinary course of computing advances, which accelerate 10x every five years.
For the first time, we have the technology to do ultra-high-resolution climate modeling, to jump to lightspeed and predict changes in regional extreme weather decades out.
We can achieve million-x speedups by combining three technologies: GPU-accelerated computing; deep learning and breakthroughs in physics-informed neural networks; and AI supercomputers, along with vast quantities of observed and model data to learn from.
And with super-resolution techniques, we may have within our grasp the billion-x leap needed to do ultra-high-resolution climate modeling.
For the first time, we have the technology to do ultra-high-resolution climate modeling, to jump to lightspeed and predict changes in regional extreme weather decades out.
We can achieve million-x speedups by combining three technologies: GPU-accelerated computing; deep learning and breakthroughs in physics-informed neural networks; and AI supercomputers, along with vast quantities of observed and model data to learn from.
And with super-resolution techniques, we may have within our grasp the billion-x leap needed to do ultra-high-resolution climate modeling.
Countries, cities and towns can get early warnings to adapt and make infrastructures more resilient.
And with more accurate predictions, people and nations will act with more urgency.
So, we will dedicate ourselves and our significant resources to direct NVIDIA’s scale and expertise in computational sciences, to join with the world’s climate science community.
NVIDIA this week revealed plans to build the world’s most powerful AI supercomputer dedicated to predicting climate change.
So, we will dedicate ourselves and our significant resources to direct NVIDIA’s scale and expertise in computational sciences, to join with the world’s climate science community.
NVIDIA this week revealed plans to build the world’s most powerful AI supercomputer dedicated to predicting climate change.
Named Earth-2, or E-2, the system would create a digital twin of Earth in Omniverse.
All the technologies we’ve invented up to this moment are needed to make Earth-2 possible.
All the technologies we’ve invented up to this moment are needed to make Earth-2 possible.
I can’t imagine a greater or more important use.
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