Israeli and German scientists announced the development of a method to capture nearly all the light emitted by microscopic defects in diamonds – an advance that could make quantum devices faster, more reliable, and easier to integrate into existing systems.<\/p>\n
Researchers at the Hebrew University of Jerusalem<\/a>, in collaboration with Humboldt University in Berlin, focused on nitrogen-vacancy (NV) centers, tiny imperfections in diamond crystals that emit single particles of light, or photons, carrying quantum information. These photons are essential for developing next-generation quantum computers, secure communications, and precision sensors. Until now, most of this light scattered in all directions, making it difficult to harness for practical applications.<\/p>\n By embedding nanodiamonds containing NV centers into specially designed hybrid nanoantennas, the researchers managed to guide the light in a precise direction instead of letting it dissipate. The antennas, constructed from layers of metal and dielectric materials in a bullseye pattern, work best when the nanodiamonds are positioned exactly at their centers – down to a few billionths of a meter.<\/p>\n The result is a dramatic improvement: up to 80 percent of photons are captured at room temperature, a major leap over previous methods.<\/p>\n An aerial view of Hebrew University of Jerusalem’s Mount Scopus campus. (credit: MARC ISRAEL SELLEM)<\/p>\n The findings were published inAPL Quantum, a peer-reviewed journal.<\/p>\n Findings ‘bring us much closer to practical quantum devices’<\/p>\n \u201cThis brings us much closer to practical quantum devices,\u201d said Prof. Carmichael Rapaport of the Hebrew University. \u201cBy making photon collection more efficient, we\u2019re opening the door to technologies such as secure quantum communication and ultra-sensitive sensors.\u201d<\/p>\n Dr. Yonatan Lubotzky added, \u201cWhat excites us is that this works in a simple, chip-based design and at room temperature. That means it can be integrated into real-world systems much more easily than before.\u201d<\/p>\n The advance demonstrates that diamonds, long prized for their sparkle, may also be essential tools in cutting-edge technology. By allowing scientists to control and collect single photons with unprecedented efficiency, this work could accelerate the deployment of quantum networks, enhance the performance of quantum computers, and enable sensors capable of detecting the smallest environmental changes.<\/p>\n Efficient photon collection is critical for quantum-secured communications, which could make data transfers virtually unhackable. Because quantum sensors can detect magnetic fields<\/a>, temperature changes, or other phenomena with unprecedented precision, the study could lead to ultra-sensitive devices for medicine, navigation, and materials science.<\/p>\n![\"An](\"https:\/\/www.europesays.com\/us\/wp-content\/uploads\/2025\/09\/ed8a355be605b5aaad00f1c80bdf0f1f.jpeg\"\/)
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