Quantum computers promise revolutionary computational power, but they face a major challenge: the inherent susceptibility of quantum systems to errors. To enable the reliable execution of quantum algorithms, we focus on developing and implementing powerful quantum error correction techniques.

We analyze and optimize quantum error correction protocols, test them in realistic simulations and across various hardware platforms. Additionally, we develop innovative tools that embed error protection directly into the structure of quantum circuits. Our approach is based on hardware-software co-design, allowing for customized error correction tailored to specific quantum hardware.

Beyond research, we place a strong emphasis on knowledge transfer. Through a comprehensive training program, we support a wide range of learners—from quantum beginners to software developers and researchers—in understanding, applying, and advancing quantum error correction.

Our goal is to lay the foundation for practical quantum algorithms and actively shape the future of quantum computing. By contributing to the transition of quantum computers from experimental systems to robust, everyday computing machines, we help enable a future where complex quantum algorithms can be executed reliably and efficiently.