Quantum Key Distribution achieves a new milestone over 100 km
by Robert Schreiber
Berlin, Germany (SPX) Apr 03, 2024

In a significant leap for quantum cryptography, the Technical University of Denmark's researchers have extended the reach of secure quantum communication. By utilizing Continuous Variable Quantum Key Distribution (CV QKD), the team achieved quantum-secure key distribution across an unprecedented 100 km distance via fiber optic cables. This milestone demonstrates the compatibility of advanced quantum encryption with existing internet infrastructure, addressing one of the major challenges in the quantum realm: maintaining quantum coherence over long distances.

The advent of quantum computing poses a formidable threat to conventional encryption methods that safeguard our digital communications. While quantum computers have yet to break current encryption standards, their potential to do so necessitates the development of quantum-resistant encryption technologies.

CV QKD represents a cutting-edge approach to secure key distribution, a cornerstone of data encryption, by leveraging the quantum states of light particles (photons) to generate uncrackable keys. In this process, any interception attempt inherently alters the quantum state of the photons, rendering the key secure from eavesdropping. This mechanism ensures the integrity of data transfers, crucial for protecting sensitive information across various sectors.

Tobias Gehring, an associate professor at DTU, highlighted the project's aim to facilitate global quantum-encrypted information distribution through the internet. The success of this endeavor hinges on overcoming photon loss and other challenges inherent to transmitting quantum states over long distances.

The experiment, detailed in the publication "Long-distance continuous-variable quantum key distribution over 100 km fiber with local local oscillator" in Science Advances, marks a significant advancement in the field of quantum cryptography. It underlines the potential of CV QKD technology to safeguard critical infrastructure against the future threats posed by quantum computing.

Machine learning techniques have played a pivotal role in enhancing the system's efficiency, particularly in noise reduction and error correction, crucial for maintaining the fidelity of quantum key distribution over extended distances. The research team's future goals include establishing a secure communication network for Danish ministries and facilitating quantum-safe links between major cities, furthering the practical applications of this new technology.

Research Report:Long-distance continuous-variable quantum key distribution over 100 km fiber with local local oscillator

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