The European Commission has announced a significant advancement in quantum technology research by launching the QuantERA 2025 call for proposals, supported by 34 funding organizations across 29 countries and totaling approximately €53 million in funding. Out of over 1,400 research teams and 287 submitted applications, only 39 projects have been selected for funding, highlighting the competitive nature of this initiative. Among these is a groundbreaking project titled “Semidefinite Foundations for Quantum Codes: Convergence, Boundaries and Constructions,” led by researchers from Paderborn University in collaboration with partners from Berlin, Poland, France, and Slovenia. This project aims to develop the mathematical underpinnings critical for the next generation of quantum codes, which are essential for constructing fault-tolerant quantum computers.
Quantum computing, often hailed as a transformative technology of the 21st century, promises unparalleled computational capabilities by solving problems that traditional computers cannot efficiently handle. Dr. Sevag Gharibian, a researcher specializing in quantum computing at the Institute for Photonic Quantum Systems (PhoQS) and the Institute of Computer Science at Paderborn University, emphasizes the importance of enhancing fault tolerance in quantum systems. “Quantum computers solve the most complex computational problems, surpassing classical hardware limits,” says Dr. Gharibian, who is focusing on algorithms designed to improve the resilience of quantum computers to errors.
Fault tolerance in quantum computing largely depends on effective quantum error correction, a mechanism that combats quantum noise and information loss intrinsic to quantum systems. However, current knowledge of the fundamental limits and design principles of quantum error correction methods is limited. Addressing this gap, the project proposes a novel approach using semidefinite programming—a technique that extends linear optimization to matrices. Instead of optimizing a scalar value, the team seeks to identify the optimal matrix meeting specific criteria to minimize error rates in quantum codes.
This innovative framework is expected to yield broad theorems, benchmark datasets, and open-source software, facilitating practical implementations in quantum error correction, resource estimation, and quantum simulations. By constructing a mathematically rigorous toolkit, the project aims to streamline the design of quantum codes, providing a robust foundation for scalable and efficient quantum computing architectures.
Paderborn has established itself as a prominent hub for quantum research, drawing expertise from physics, mathematics, electrical engineering, and computer science. The interdisciplinary efforts at PhoQS exemplify this synergy, as scientists work collaboratively to position the region as an international leader in photonic quantum technologies. Notably, in 2024, Germany’s first photonic quantum computer, known as PaQS, commenced operations at Paderborn University, marking a milestone in light-based quantum computing.
Dr. Gharibian underscores the strategic value of participating in the QuantERA network: “Being part of QuantERA allows us to strengthen European quantum technology collaboration and ensures that Europe remains competitive in the global race for quantum innovation.” This collaboration positions Paderborn University at the forefront of quantum technology research, contributing significantly to one of the most critical technological frontiers of this era.
As quantum computing continues to gather momentum worldwide, projects like these embody the essential blend of theoretical mathematics and applied physics required to overcome the intrinsic challenges of quantum error correction. The novel use of semidefinite programming to analyze and construct quantum codes promises both a deeper understanding and more practical routes towards fault-tolerant quantum computers, heralding a new chapter in quantum technology.
Subject of Research: Quantum error correction and fault-tolerant quantum computing
Article Title: European Initiative Advances Mathematical Foundations for Fault-Tolerant Quantum Codes
News Publication Date: Not specified
Web References: https://phoqs.uni-paderborn.de/ | https://cs.uni-paderborn.de/ | https://www.uni-paderborn.de/thema/quantenforschung
Keywords: Quantum computing, fault tolerance, quantum error correction, semidefinite programming, quantum codes, photonic quantum technologies, QuantERA, Paderborn University

