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Twisting Quantum Potential Into Reality
thequantuminsider.com Jun 23, 2026

Twisting Quantum Potential Into Reality

Curated by · TechCapsules ·

AI-summarised brief · reviewed before publication

Researchers at the University of Technology Sydney, in collaboration with the University of Minnesota and Kyung Hee University, have developed a method for controlling quantum light sources in hexagonal boron nitride. This breakthrough involves twisting and restacking the layered material to shift the colour and wavelength of emitted quantum light. The approach has significant potential for practical quantum technologies, including quantum computing, secure communications, and ultra-sensitive sensing.

💡 Why It Matters

  • · This discovery unlocks new physics by leveraging the layered structure of hexagonal boron nitride, allowing for unprecedented control over quantum light sources.
  • · By twisting and restacking the material, researchers can shift the emission by a significant amount, bringing them closer to realising practical quantum technologies.
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