Stuttgart Scientists Teleport Quantum Information Between Distant Photons

Researchers at the University of Stuttgart have achieved a major milestone in quantum technology. They successfully teleported quantum information between photons created by two distant light sources. As a result, the goal of building secure quantum networks now feels closer than ever.Cyberattacks continue to grow more advanced. However, quantum cryptography offers a safer path by protecting data through the laws of physics. Any attempt to intercept a quantum signal creates visible traces, which makes tampering harder.

How the Teleportation Works

The team at the Institute of Semiconductor Optics and Functional Interfaces developed a system that transfers fragile quantum states without revealing them. They worked with tiny semiconductor structures known as quantum dots. These structures can create individual photons with very specific properties.According to the researchers, the key challenge came from the need for identical photons. Photons from different locations normally vary slightly in color or timing. Therefore, teleporting information between them becomes extremely difficult.The team solved this by using advanced quantum dots that produce nearly identical light particles. In addition, they used quantum frequency converters to correct any remaining differences. This allowed the light from separate sources to overlap perfectly.

A New Step Toward Quantum Repeaters

During the experiment, one quantum dot created a single photon, while another produced an entangled pair. When one photon from the pair interacted with the single photon, the information transferred instantly to the second photon. This process is the foundation of a future quantum repeater.The current distance between their quantum dots was only 10 meters. However, earlier studies show their photons can travel much farther while staying linked. The team now aims to extend the teleportation distance and improve the success rate.They believe this work marks a meaningful step toward a secure and scalable quantum internet.