Quantum leap: Particle teleported over public internet

Scientists from the McCormick School of Engineering at Northwestern University achieved a breakthrough in the field of quantum teleportation. According to research published in the journal "Optica," for the first time in history, a particle was successfully transmitted over 29 kilometres of public internet infrastructure.

Quantum teleportation is a phenomenon within quantum physics, involving the transfer of a quantum state from one particle to another, even over long distances. Contrary to the common understanding of teleportation, it does not involve the physical movement of matter, but rather the transmission of information about the particle's state through quantum entanglement. Two particles are brought into an entangled state, meaning a change in the state of one immediately affects the state of the other. This allows the "transfer" of the state of particle A to particle B, even though object A remains in its place.

This process requires a classical communication channel and does not violate the speed of light constraint, but it shows how extraordinary the laws governing the quantum world are. Previous attempts required dedicated channels such as fibre optics. This time, it was achieved through existing internet channels, which is a huge step forward.

The quantum internet is the communication network of the future. This system is based on the principles of quantum mechanics. Unlike the traditional internet, where data is encoded in bits taking values of 0 or 1, the quantum internet uses qubits that can exist in a superposition of both states simultaneously. This makes it possible to create secure connections that are immune to eavesdropping, as any attempt to intercept information disturbs the quantum state and is immediately detected.

This groundbreaking achievement opens doors to a future where the quantum internet can coexist with current data networks. This eliminates the need to build new data transmission systems. According to the portal Popular Mechanics, this discovery could accelerate the development of quantum technologies, such as cryptography and artificial intelligence.

The success of the experiment was influenced by minimizing interference that could affect the quantum signal. It was discovered that a key aspect of quantum teleportation is the appropriate conditions for photon emission, allowing it to maintain coherence among other data transmitted over the internet.

The quantum internet, like the current one, will rely on a network of distributed nodes and transmission systems. Thanks to this discovery, there will be no need to create new infrastructures, which will speed up the implementation of this technology.