Our partners from TU Munich created a webpage that provides an overview of the emerging quantum security landscape, focusing on quantum key distribution (QKD) and its relevance to IT decision-makers. It explains the potential impact of quantum technologies on current cryptographic systems and highlights key considerations for organizations preparing for quantum-safe security strategies. The page aims to support informed decision-making by outlining opportunities, challenges, and practical implications of adopting quantum-secure communication technologies.

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With the approaching Q-Day - when quantum computers may become powerful enough to break today’s encryption methods - Quantum Key Distribution (QKD) is coming into focus as a protective measure. Although QKD holds great potential, its current area of application remains limited. Chief Information Security Officers (CISOs) have legitimate concerns regarding security, cost, scalability, and integration. Early engagement with quantum technologies is essential to counter future threats.

Press release from csoonline

We are excited to announce a major milestone in our research project Q-net-Q: the successful deployment of the first quantum key distribution (QKD) link in Testbed 4. The link, spanning approximately 70 km between Sundhausen and Nordhausen University of Applied Sciences, is based on an entanglement-based QKD system called Elvis, provided by Quantum Optics Jena (QOJ).

This installation pushes the limits of what is possible with this type of QKD system. The connection consists of 70 km of dark fiber, including 19 km of overhead lines, making it an ambitious and technically demanding endeavor. To create a real-world scenario, we deliberately used SPAD (Single-Photon Avalanche Diode) detectors instead of SNSPDs (Superconducting Nanowire Single-Photon Detectors). While SPADs have a more limited range, they offer significant advantages in cost-effectiveness and maintainability, making them a practical choice for real-world applications.

Achieving stable key generation required extensive fine-tuning, but thanks to the expertise and support of the team from QOJ, we have successfully overcome these challenges. With secure quantum keys now being generated, this deployment also serves as a valuable real-world testbed for advancing quantum communication infrastructure.

We extend our gratitude to Quantum Optics Jena for their collaboration and expertise in making this milestone possible. This achievement sets the stage for further advancements in the Q-net-Q project as we continue exploring the frontiers of quantum communication technologies.

Stay tuned for more updates as we expand and enhance our quantum network!

At the end of October, the Nordhausen University of Applied Sciences hosted a hands-on workshop on quantum key distribution (QKD), bringing together over 20 experts and enthusiasts to explore innovations in IT security. The event, organized as part of the EU-funded Q-net-Q project, focused on practical applications of QKD for critical infrastructures, showcasing its potential in sectors like healthcare, energy, and telecommunications to ensure secure, quantum-resistant data transmission.

Press release from Nordhausen University of Applied Sciences

The Free State of Thuringia wants to become an important hub for the German quantum network. The state, federal government and the European Union are driving the expansion of a network for quantum communication in Germany with various projects.

Press release from Nordhausen University of Applied Sciences

Press release from Fraunhofer IOF

The ‘Q-net-Q’ project aims to integrate quantum key distribution (QKD) into existing information and communication systems in order to increase IT security in increasingly digitalised infrastructures. It creates test fields to trial the technology in real networks and drive forward technology transfer to promote a pan-European quantum communication infrastructure.

Press release from BMBF