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Nvidia’s Quantum Computing Efforts Accelerated at Global Supercomputing Centers
Nvidia has recently made strides in advancing quantum computing efforts at national supercomputing centers worldwide through the introduction of the open-source Nvidia CUDA-Q platform. This platform will be utilized by supercomputing sites in Germany, Japan, and Poland to enhance the capabilities of the quantum processing units (QPUs) within Nvidia-accelerated high-performance computing systems.
The collaboration between Nvidia and these supercomputing centers has led to the deployment of nine new supercomputers utilizing Nvidia Grace Hopper Superchips. These systems collectively deliver an impressive 200 exaflops of energy-efficient AI processing power, facilitating significant advancements in scientific research and discovery across various fields.
Germany’s Jülich Supercomputing Centre (JSC)
In Germany, the Jülich Supercomputing Centre, based at Forschungszentrum Jülich (FZJ), is integrating a QPU provided by IQM Quantum Computers into its Jupiter supercomputer. This QPU, powered by the Nvidia GH200 Grace Hopper Superchip, will enable researchers to explore quantum applications in AI, energy, and biology using Rubidium atoms controlled by laser light as qubits.
ABCI-Q Supercomputer in Japan
Over in Japan, the National Institute of Advanced Industrial Science and Technology (AIST) hosts the ABCI-Q supercomputer, equipped with a QPU from QuEra and powered by the Nvidia Hopper architecture. This setup will advance Japan’s quantum computing initiative by allowing researchers to delve into various fields such as AI, energy, and biology, leveraging Rubidium atoms as qubits for calculations.
Poland’s Poznan Supercomputing and Networking Center (PSNC)
In Poland, the Poznan Supercomputing and Networking Center has recently incorporated two photonic QPUs from ORCA Computing into a new supercomputer partition accelerated by the Nvidia Hopper platform. These QPUs will enable researchers to explore biology, chemistry, and machine learning using quantum photonics systems, offering a novel approach to quantum computing.
Overall, Nvidia’s quantum computing platform aims to facilitate the integration of quantum with GPU supercomputing, empowering researchers to push the boundaries of scientific discovery and achieve breakthroughs in quantum-integrated supercomputing.
Nvidia’s Grace Hopper Superchips Enhance Scientific Research
Nvidia’s Grace Hopper Superchips are making significant contributions to scientific research and discovery by accelerating operations in nine supercomputing centers globally. These supercomputers, powered by Grace Hopper Superchips, are driving advancements in various fields through their energy-efficient AI processing capabilities.
Notable supercomputing centers leveraging Nvidia Grace Hopper Superchips include EXA1-HE in France, Helios in Poland, Alps in Switzerland, and other cutting-edge systems in Germany, Japan, and the United States. These supercomputers play a vital role in accelerating research into climate change, drug discovery, and other crucial areas, showcasing the transformative power of Nvidia’s chip technology.
The collaboration between Nvidia and these supercomputing centers underscores a commitment to innovation and efficiency, with a focus on developing more sophisticated AI-based supercomputers. By harnessing the capabilities of Nvidia Grace Hopper Superchips, these centers are advancing research efforts and driving progress in scientific endeavors.
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