Gordon Bell Prize Finalists Push Open Science Boundaries With NVIDIA-Powered Supercomputers

5 finalists for the Gordon Bell Prize for excellent achievements in high-performance computing (HPC) are utilizing NVIDIA-powered supercomputers for his or her crucial work in local weather modeling, supplies science, fluid simulation, geophysics and digital design.

Introduced immediately at SC25, the finalists’ initiatives are driving AI and HPC for science utilizing physics simulation, high-precision math and different superior supercomputing methods, accelerating breakthroughs throughout climate forecasting, semiconductor design, area exploration and different fields. Their outcomes are open and accessible on ArXiv.

The supercomputers powering their work embrace:

• Alps — hosted on the Swiss Nationwide Supercomputing Centre (CSCS) and powered by greater than 10,000 NVIDIA GH200 Grace Hopper Superchips. 
• Perlmutter — hosted on the Nationwide Vitality Analysis Scientific Computing Middle (NERSC) and powered by NVIDIA accelerated computing.
• JUPITER — Europe’s first exascale supercomputer, hosted on the Jülich Supercomputing Centre (JSC) and powered by the NVIDIA Grace Hopper platform and Quantum-X800 InfiniBand networking.

“At CSCS, we don’t simply assist open science — we speed up it,” stated Thomas Schulthess, director of CSCS. “The extraordinary breakthroughs by this 12 months’s 5 Gordon Bell finalists in local weather modeling, supplies science, fluid dynamics and digital twins stand as irrefutable proof: with out the Alps supercomputer, these scientific discoveries merely wouldn’t exist. Pushing computational boundaries turns daring targets into actuality, delivering scientific revolutions that may redefine our world.”

Study extra in regards to the 5 finalists’ initiatives beneath.

A novel configuration for the ICON Earth system mannequin — developed by researchers on the Max Planck Institute for Meteorology, German Local weather Computing Centre (DKRZ), CSCS, JSC, ETH Zurich and NVIDIA — is poised to allow extra correct climate forecasts and a deeper understanding of how the planet works. 

By modeling your complete Earth’s programs at kilometer-scale decision, ICON can seize the circulation of vitality, water and carbon by the ambiance, oceans and land with distinctive element and unprecedented temporal compression — permitting about 146 days to be simulated each 24 hours — which allows extra environment friendly local weather simulations projecting as much as many years ahead.

“Integrating all important elements of the Earth system within the ICON mannequin at an unprecedented decision of 1 kilometer permits researchers to see full international Earth system info on native scales and be taught extra in regards to the implications of future warming for each folks and ecosystems,” stated Daniel Klocke, computational infrastructure and mannequin improvement group chief at Max Planck Institute for Meteorology.

Developed as a part of a collaboration between Oak Ridge Nationwide Laboratory, NVIDIA and others — and working on the Alps supercomputer — ORBIT-2 is an AI basis mannequin for climate and local weather downscaling that demonstrates unparalleled scalability and precision.

Tapping into exascale computing and algorithmic innovation, ORBIT-2 overcomes challenges confronted by conventional local weather fashions with spatial hyper-resolution downscaling, a method that creates high-resolution information from lower-resolution sources. This permits groups to seize and predict way more localized phenomena like city warmth islands, excessive precipitation occasions and refined shifts in monsoon patterns.

“NVIDIA’s superior supercomputing applied sciences enabled ORBIT-2 to attain distinctive scalability, reliability and affect on the intersection of AI and high-performance computing on NVIDIA platforms,” stated Prasanna Balaprakash, director of AI applications and part head for information and AI programs at Oak Ridge Nationwide Laboratory.

A crew from ETH Zurich has superior nanoscale digital machine modeling with QuaTrEx, a package deal of algorithms that may increase the design of next-generation transistors.

Operating on the Alps supercomputer with NVIDIA GH200 Superchips, QuaTrEx can simulate units with greater than 45,000 atoms with FP64 efficiency and excessive parallel-computing effectivity. This permits sooner, extra correct design of transistors, referred to as NREFTs, that might be essential for the semiconductor business.

“Entry to Alps was instrumental within the improvement of QuaTrEx,” stated Mathieu Luisier, full professor of computational nanoelectronics at ETH Zurich. “It allowed us to simulate units that we couldn’t think about dealing with only a few months in the past.”

Designing spacecrafts, particularly these with many small engines, requires detailed simulation, as engines packed intently collectively could cause their exhaust to work together and warmth up a rocket’s base. 

Operating on the Alps supercomputer, MFC, an open-source solver developed by the Georgia Institute of Know-how in collaboration with NVIDIA and others, allows fluid circulation simulation 4x sooner and with over 5x larger vitality effectivity whereas sustaining the identical accuracy because the earlier world document. Primarily based on full-scale runs on Alps, MFC is predicted to run at 10x the size of the earlier world document on JUPITER. This paves the best way for sooner, extra correct design of crucial elements for area exploration.

“Our new info geometric regularization methodology, mixed with the NVIDIA GH200 Superchip’s unified digital reminiscence and mixed-precision capabilities, has drastically improved the effectivity of simulating complicated computational fluid flows, enabling us to simulate rocket engine plumes at unprecedented scales,” stated Spencer Bryngelson, assistant professor in computational science and engineering on the Georgia Institute of Know-how.

The College of Texas at Austin, Lawrence Livermore Nationwide Laboratory and the College of California San Diego have created the world’s first digital twin that may difficulty real-time probabilistic tsunami forecasts based mostly on a full-physics mannequin. 

Utilized to the Cascadia subduction zone within the Pacific Northwest, the digital twin achieved complicated computations that might usually take 50 years on 512 GPUs in simply 0.2 seconds on the Alps and Perlmutter supercomputers, representing a ten billion-fold speedup.

“For the primary time, real-time sensor information will be quickly mixed with full-physics modeling and uncertainty quantification to present folks an opportunity to behave earlier than catastrophe strikes,” stated Omar Ghattas, professor of mechanical engineering at UT Austin. “This framework supplies a foundation for predictive, physics-based emergency-response programs throughout numerous hazards.”

For the tsunami digital twin, ICON and MFC initiatives, NVIDIA CUDA-X libraries performed a key function in maximizing the efficiency and effectivity of the complicated simulations. ICON additionally faucets into NVIDIA CUDA Graphs, which permit work to be outlined as graphs relatively than single operations.

Study extra in regards to the newest supercomputing developments by becoming a member of NVIDIA at SC25, working by Thursday, Nov. 20.