Researchers from the Department of Physics at the Humboldt University of Berlin have made significant breakthroughs in understanding the scattering of light by a single fluorescent atom. Their findings, published in the journal Nature Photonics, not only provide new insights into fundamental physics but also have potential applications in the field of quantum communication.

In 1900, Max Planck introduced the concept of quanta, discrete packets of energy that light exchanges with matter. Albert Einstein later developed the theory that light itself consists of these quanta, now known as photons. Modern technology has advanced to the point where photodiodes can detect the presence of a single photon. When a single atom, excited by a laser beam, emits fluorescent light, its photons do not occur simultaneously, unlike laser light. However, if two laser photons strike a single atom simultaneously, the atom will absorb only one, allowing the other to pass through before radiating the absorbed photon in a random direction.

The research team at the Humboldt University made a surprising discovery when they removed a specific color component from the fluorescent light emitted by a single atom using a filter. Instead of observing a single stream of photons, they found that the stream transformed into pairs of photons that were detected simultaneously. This effect contradicts our everyday understanding of the world; removing green cars from a street does not cause the remaining cars to suddenly drive in pairs. Additionally, it challenges the previous belief that a single atom can only scatter one photon at a time. Through the correct color filter, the atom was able to scatter two photons simultaneously.

The observation of photon pairs generated from a single atom is not only a fascinating phenomenon but also has practical implications. The generated photon pairs are quantum mechanically entangled, meaning there is a mysterious correlation between the two photons that Einstein famously doubted. This entanglement enables the teleportation of quantum states and offers potential for quantum communication. The team led by Jürgen Volz and Arno Rauschenbeutel highlights the fact that a single atom can act as an ideal source for entangled photon pairs. This unexpected discovery opens new possibilities for creating brighter sources of entangled photons, surpassing existing sources. Furthermore, the entangled photon pairs are inherently matched to the atoms from which they were emitted, enabling direct integration with quantum repeaters or quantum gates used in long-distance quantum communication.

The findings of this research demonstrate the limitations of human intuition when it comes to understanding processes at the microscopic level. The behavior of light and atoms at such scales defies our everyday notions of causality and predictability. The team emphasizes the importance of exploring these counterintuitive phenomena to further our understanding of the quantum world and expand the possibilities of quantum technologies.

The research conducted by the team at the Humboldt University of Berlin sheds light on the scattering of light by single fluorescent atoms and reveals unexpected effects that challenge our intuition. The transformation of a single photon stream into pairs of photons by removing a specific color component from the light is a remarkable discovery with implications for quantum communication. The generation of entangled photon pairs from single atoms opens doors to brighter and more efficient sources of entangled photons, enabling advancements in long-distance quantum communication. This research serves as a reminder that our understanding of the microscopic world is far from complete, and there are still many discoveries to be made in the field of quantum physics.

Science

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