Summary:
- Frontier system at Oak Ridge National Laboratory maintains second place with an HPL score of 1.353 EFlop/s.
- Aurora system at Argonne Leadership Computing Facility holds third place with a benchmark of 1.012 EFlop/s.
- JUPITER at EuroHPC/Jülich Supercomputing Centre in Germany secures fourth place with a performance of 1 Exaflop.
Rewritten Article:
H1: Latest Updates on Top Supercomputers in the World
H2: Frontier System at Oak Ridge National Laboratory
The Frontier system at Oak Ridge National Laboratory continues to impress, holding onto its second-place position with an impressive HPL score of 1.353 EFlop/s. Powered by HPE Cray EX235z architectures and AMD third-generation EPYC 64C 2GHz processors, the system boasts a total of 9,066,176 cores. It relies on the HPE Slingshot interconnect for seamless data transfer, solidifying its status as a powerhouse in the world of supercomputing.
H2: Aurora System at Argonne Leadership Computing Facility
Securing the third spot on the list is the Aurora system at the Argonne Leadership Computing Facility, showcasing a benchmark of 1.012 EFlop/s. Built by Intel and based on the HPE Cray EX-Intel Exascale Compute Blade, this system is a force to be reckoned with. Utilizing the HPE Slingshot interconnect and Intel Xeon CPU Max Series processors, the Aurora system demonstrates exceptional performance and reliability.
H2: JUPITER at EuroHPC/Jülich Supercomputing Centre
Making its mark in fourth place is JUPITER at the EuroHPC/Jülich Supercomputing Centre in Germany. Initially commissioned during the last listing, JUPITER has now fully deployed and achieved a remarkable benchmark of 1 Exaflop performance. Built on Eviden’s BullSequana XH3000 direct liquid-cooled architecture and powered by Nvidia Grace Hopper GH200 chips, this system boasts a total of 4,801,344 cores. JUPITER is a testament to the cutting-edge technology driving the future of supercomputing.
In conclusion, these top supercomputers continue to push the boundaries of performance and innovation, solidifying their positions as leaders in the global supercomputing landscape. Each system brings unique strengths and capabilities to the table, contributing to advancements in research, simulation, and computational tasks on a massive scale. The future of supercomputing looks brighter than ever, with these powerhouse systems at the forefront of technological evolution.
