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Home » IonQ Demonstrates 12% Speed Advantage Over Classical HPC

IonQ Demonstrates 12% Speed Advantage Over Classical HPC

March 20, 2025
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IonQ claims its production quantum system has outperformed classical computing methods in a real-world simulation for medical device design, marking a key milestone for the quantum industry. Working alongside Ansys, a leader in computer-aided engineering (CAE), IonQ demonstrated a 12% speed improvement using its IonQ Forte quantum computer to optimize blood pump dynamics. The project involved running hybrid quantum-classical simulations to model fluid interactions within medical devices, resulting in faster and more efficient processing compared to conventional high-performance computing (HPC) methods.

The test handled simulations involving up to 2.6 million vertices and 40 million edges, a scale common in computational fluid dynamics (CFD) applications. IonQ’s optimization techniques enabled Ansys to reduce processing times in LS-DYNA workflows, a widely used tool in life sciences and medical engineering. IonQ’s proprietary quantum optimization method, used in this project, is applicable across industries, with potential use cases in automotive safety simulations, supply chain optimization, and financial modeling.

This collaboration represents one of the first documented cases of quantum outperforming classical computing on a practical engineering task. It also highlights how quantum computing is increasingly being integrated into mainstream design and simulation workflows. IonQ’s milestone points to a growing trend of hybrid quantum-HPC workflows becoming commercially viable as quantum hardware matures.

Key Points:

• IonQ demonstrated 12% faster performance over classical computing in a real-world simulation with Ansys.

• The hybrid quantum-classical workflow optimized blood pump dynamics in medical device design.

• IonQ’s Forte system successfully handled simulations with up to 2.6 million vertices and 40 million edges.

• IonQ’s quantum optimization methods are adaptable to industries such as automotive, logistics, and finance.

• Marks one of the first cases of quantum outperforming classical HPC methods in engineering workflows.

“This demonstration is a significant achievement for IonQ and the quantum computing industry as a whole,” said Niccolo de Masi, President and CEO, IonQ. “We’re showcasing one of the first cases ever where quantum computing is outperforming key classical methods, demonstrating real-world improvements for practical applications that will grow as our quantum hardware advances.”

  • IonQ, based in College Park, Maryland, is a pioneer in trapped-ion quantum computing technology. The company is led by President and CEO Niccolo de Masi and is focused on delivering scalable quantum computing solutions for commercial and research applications. IonQ’s flagship systems, such as IonQ Forte, are designed to accelerate optimization, machine learning, and quantum chemistry simulations. The company partners with enterprises across sectors including aerospace, automotive, and life sciences to develop quantum-enhanced workflows.

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