On November 11, 2025, a groundbreaking achievement was announced by a collaborative team at the Jülich Supercomputing Centre and NVIDIA. For the first time, a universal quantum computer with 50 qubits has been fully simulated. This monumental feat was accomplished using Europe’s first exascale supercomputer, JUPITER, which was inaugurated at Forschungszentrum Jülich in September.
This achievement surpasses the previous record of 48 qubits, set by Jülich researchers in 2022 on Japan’s K computer. The simulation showcases JUPITER’s immense computational power and opens new horizons for the development and testing of quantum algorithms.
Significance of Quantum Simulations
Quantum computer simulations are crucial for the advancement of future quantum systems. They enable researchers to verify experimental results and test new algorithms long before powerful quantum machines become a reality. Among these algorithms are the Variational Quantum Eigensolver (VQE), which models molecules and materials, and the Quantum Approximate Optimization Algorithm (QAOA), used for optimization problems in logistics, finance, and artificial intelligence.
Pushing the Limits of Classical Computing
Simulating a quantum computer on conventional hardware presents a formidable challenge. The number of possible quantum states increases exponentially: each additional quantum bit, or qubit, doubles both the computing and memory requirements. While around 30 qubits can still be handled on a standard laptop, simulating 50 qubits demands around 2 petabytes—roughly two million gigabytes—of memory.
“Only the world’s largest supercomputers currently offer that much,” says Prof. Kristel Michielsen, Director at the Jülich Supercomputing Centre. “This use case illustrates how closely progress in high-performance computing and quantum research are intertwined today.”
The simulation replicates the intricate quantum physics of a real processor in full detail. Every operation, such as applying a quantum gate, affects more than 2 quadrillion complex numerical values, a “2” with 15 zeros. These values must be synchronized across thousands of computing nodes to precisely replicate the functioning of a real quantum processor.
Breakthrough Enabled by New Memory Technology
The record was made possible by the close coupling of central processing units (CPUs) and graphics processing units (GPUs) in NVIDIA GH200 Superchips, which are used in the JUPITER supercomputer. This design allows data that exceed GPU memory limits to be temporarily stored in CPU memory with minimal loss of performance.
To exploit this hybrid memory system, specialists at the NVIDIA Application Lab—a joint initiative between the Jülich Supercomputing Centre (JSC) and NVIDIA—enhanced Jülich’s simulation software, Jülich Universal Quantum Computer Simulator (JUQCS). The new version, JUQCS-50, now performs quantum operations efficiently even when parts of the data are offloaded to the CPU.
Further innovations include a byte-encoding compression method that reduces memory requirements eightfold and a dynamic algorithm that continuously optimizes data exchange between more than 16,000 GH200 Superchips.
“With JUQCS-50, we can emulate universal quantum computers with high fidelity and tackle questions that no existing quantum processor can yet solve,” says Prof. Hans De Raedt of the Jülich Supercomputing Centre and lead author of the study published as a preprint.
Integration into Jülich’s Quantum Infrastructure
JUQCS-50 will also be accessible to external research institutions and companies via JUNIQ—the Jülich UNified Infrastructure for Quantum Computing. It will serve both as a research tool and as a benchmark for future supercomputers.
The development took place within the framework of the JUPITER Research and Early Access Programme (JUREAP). “Through early collaboration, hardware and software could be co-designed during JUPITER’s construction phase, in close cooperation between Jülich experts and NVIDIA—an important step towards realizing the full potential of this exascale system,” explains Dr. Andreas Herten, a member of the Jülich JUPITER project team and co-author of the study.
As the field of quantum computing continues to evolve, the achievements of the Jülich Supercomputing Centre and NVIDIA represent a significant milestone. The integration of JUQCS-50 into broader research efforts will likely accelerate advancements in quantum technology, providing a robust platform for future discoveries.
