Quantum light breakthrough could transform technology
Quantum materials just broke the symmetry barrier, ushering in a new era of terahertz light and ultrafast technology.
- Date:
- November 2, 2025
- Source:
- Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS
- Summary:
- Scientists have achieved a breakthrough in light manipulation by using topological insulators to generate both even and odd terahertz frequencies through high-order harmonic generation (HHG). By embedding these exotic materials into nanostructured resonators, the team was able to amplify light in unprecedented ways, confirming long-theorized quantum effects. This discovery opens the door to new terahertz technologies with vast implications for ultrafast electronics, wireless communication, and quantum computing.
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High-order harmonic generation (HHG) is a process that transforms light into much higher frequencies, allowing scientists to explore areas of the electromagnetic spectrum that are otherwise difficult to reach. However, generating terahertz (THz) frequencies using HHG has remained a major obstacle because most materials are too symmetrical to support this conversion.
Graphene has long been a promising candidate for HHG research, but its perfect symmetry restricts it to producing only odd harmonics -- frequencies that are odd multiples of the original light source. Even harmonics, which are essential for expanding practical uses of this technology, have been much harder to achieve.
Quantum Materials Break the Barrier
In a recent study published in Light: Science & Applications, a research group led by Prof. Miriam Serena Vitiello has achieved a major advance in optical science. By working with exotic quantum materials, the team successfully extended HHG into new and previously unreachable parts of the electromagnetic spectrum.
Their work centers on topological insulators (TIs), a special class of materials that behave as electrical insulators inside but conduct electricity along their surfaces. These materials exhibit unusual quantum behavior due to strong spin-orbit coupling and time-reversal symmetry. Although scientists had predicted that TIs could support advanced forms of harmonic generation, no one had yet demonstrated it experimentally -- until now.
Amplifying Light With Quantum Nanostructures
The researchers designed specialized nanostructures called split ring resonators and integrated them with thin layers of Bi2Se₃ and van der Waals heterostructures made from (InₓBi₁₋ₓ)2Se₃. These resonators significantly intensified the incoming light, allowing the team to observe HHG at both even and odd THz frequencies, an exceptional accomplishment.
They recorded frequency up-conversion between 6.4 THz (even) and 9.7 THz (odd), uncovering how both the symmetrical interior and the asymmetrical surface of the topological materials contribute to light generation. This result represents one of the first clear demonstrations of how topological effects can shape harmonic behavior in the THz range.
Toward Next-Generation Terahertz Technology
This experimental achievement not only validates long-standing theoretical predictions but also establishes a new foundation for developing compact terahertz light sources, sensors, and ultrafast optoelectronic components. It gives researchers a new way to study the complex interplay between symmetry, quantum states, and light-matter interactions at the nanoscale.
As industries continue to demand smaller, faster, and more efficient devices, such progress highlights the growing potential of quantum materials to drive real-world innovation. The discovery also points toward the creation of compact, tunable terahertz light sources powered by optical methods -- an advance that could reshape technologies in high-speed communications, medical imaging, and quantum computing.
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Materials provided by Light Publishing Center, Changchun Institute of Optics, Fine Mechanics And Physics, CAS. Note: Content may be edited for style and length.
Journal Reference:
- Alessandra Di Gaspare, Sara Ghayeb Zamharir, Craig Knox, Ahmet Yagmur, Satoshi Sasaki, Mohammed Salih, Lianhe Li, Edmund H. Linfield, Joshua Freeman, Miriam S. Vitiello. Second and third harmonic generation in topological insulator-based van der Waals metamaterials. Light: Science, 2025; 14 (1) DOI: 10.1038/s41377-025-01847-5
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