In a pioneering advance at the crossroads of condensed matter physics and nonlinear optics, researchers have unveiled the extraordinary potential of topological insulator-based van der Waals metamaterials to generate second and third harmonic signals with unprecedented efficiency. The findings, recently published in Light: Science & Applications, open new horizons for ultrafast photonic devices and quantum technologies, leveraging the exotic electronic properties of topological materials combined with the unique structural versatility of two-dimensional van der Waals heterostructures.
Topological insulators (TIs) have captivated the scientific community for over a decade, primarily due to their peculiar electronic states that are insulating in the bulk but support robust, conductive surface states protected by time-reversal symmetry. These surface states exhibit spin-momentum locking, meaning the direction of an electron’s spin is locked perpendicular to its momentum, which suppresses backscattering and imparts remarkable resilience to disorder. The incorporation of TIs into optical metamaterials allows researchers to tap directly into these special surface phenomena, potentially revolutionizing nonlinear optical processes such as harmonic generation.
Nonlinear optics — the study of light interacting with matter beyond the linear regime — lies at the heart of many modern photonic technologies, from frequency conversion to ultrafast optical switching. Harmonic generation, where photons combine to produce new photons at integer multiples of the original frequency, is particularly vital for applications ranging from generating coherent ultraviolet and X-ray radiation to developing compact quantum light sources. Second harmonic generation (SHG) and third harmonic generation (THG) are nonlinear processes that depend sensitively on symmetry properties of a material. The ability to boost these processes efficiently in engineered metamaterials is thus a subject of immense scientific interest and technological demand.
The research team, led by Di Gaspare and colleagues, cleverly exploits the van der Waals assembly approach wherein atomically thin layers of topological insulator crystals are stacked with other 2D materials to form metamaterials with tailored optical responses. This approach leverages the weak interlayer forces allowing precise control over electronic coupling and optical interactions at the interfaces, yielding emergent phenomena not present in either constituent alone. By meticulously designing these engineered heterostructures, the scientists achieved significant enhancement in both second and third harmonic signals compared to individual TI layers or conventional nonlinear materials.
A central find in the study is the remarkably strong SHG and THG signals stemming from the topological surface states intertwined with the carefully crafted van der Waals environment. Typically, harmonic generation in TIs faces challenges due to centrosymmetric crystal structures that suppress even-order nonlinearities like SHG in the bulk. However, the surface states break inversion symmetry locally, enabling robust nonlinear optical activity. Additionally, coupling these surface states with adjacent 2D layers amplifies the nonlinear susceptibility by facilitating resonant electronic transitions and field confinement, leading to enhanced photon conversion efficiencies.
To unravel the nonlinear optical response quantitatively, the team utilized ultrafast laser spectroscopy in the visible to near-infrared regimes, sending femtosecond pulses into the samples and measuring the resulting harmonic emissions with sensitive photon detectors. The spectral and polarization dependencies of the harmonics revealed insights into the symmetry and electronic band topology. Notably, the nonlinear susceptibility tensors extracted from experimental data differ markedly from those of traditional nonlinear crystals, reflecting the unique spin-helical nature of the TI surface electrons and their interplay with the metamaterial structure.
The implications of these findings stretch well beyond fundamental science. In the realm of photonic devices, the enhanced harmonic generation could lead to compact, tunable frequency converters for integrated on-chip optical systems, essential for future optical communication and computing architectures. Furthermore, the control of nonlinear processes via topological surface states hints at new schemes for spin-photon interfaces, opening avenues toward robust quantum light sources and interfaces for spin-based quantum information processing.
Moreover, the integration of van der Waals engineering allows unprecedented flexibility to tailor nonlinear optical properties on demand. By varying the stacking order, layer thicknesses, and constituent materials, the metamaterials can be tuned to optimize harmonic conversion at specific wavelengths relevant to telecommunications, biomedical imaging, or environmental sensing. This level of control, combined with the intrinsic robustness of topological states, potentially offers devices that maintain performance under harsh conditions, a substantial advantage over fragile conventional components.
Another exciting aspect is related to the ultrafast dynamics of these harmonic processes. The spin-momentum locked surface states have inherently rapid relaxation times, enabling femtosecond-scale nonlinear responses suitable for high-speed optical modulation. This rapidity makes TI-based van der Waals metamaterials not only efficient frequency converters but also promising candidates for ultrafast optical switches, modulators, and detectors, critical for advancing photonic integrated circuits.
In addition to experimental breakthroughs, the study features comprehensive theoretical modeling to understand the microscopic mechanisms driving the nonlinear optical behavior. Through ab initio simulations coupled with effective models capturing spin-orbit coupling and electronic topology, the researchers confirmed that the nonlinear optical susceptibility is strongly influenced by the Dirac fermion nature of TI surface states and their hybridization in layered structures. These calculations provide design rules for future metamaterials tailored toward even higher harmonic orders or alternative nonlinear phenomena such as four-wave mixing or optical Kerr effects.
The combination of detailed spectroscopic analysis, theoretical insights, and practical material engineering sets a new standard for harnessing topological phases in photonics. Whereas previous studies mostly focused on linear optical signatures of topological insulators, this work pushes the frontier into the nonlinear regime, where new physics and functionalities emerge from the interplay of topology, symmetry breaking, and electron–photon interactions. It places van der Waals heterostructures firmly at the center of next-generation nonlinear photonic materials.
Looking ahead, challenges remain in scaling these results for widespread applications, such as fabricating large-area, uniform metamaterial films and integrating them with current photonic platforms. Nevertheless, the demonstration of strong second and third harmonic generation in TI-based van der Waals metamaterials is a landmark that promises to inspire further exploration across disciplines — from material science and condensed matter physics to applied photonics and quantum engineering.
This breakthrough underscores the growing importance of layered materials and topological matter in practical technology, bridging gaps between abstract quantum phenomena and device-level realities. As nonlinear optics continues to drive innovation in communication, sensing, and computation, the insights gained from topological insulator van der Waals metamaterials will likely catalyze new classes of photonic devices blending quantum robustness with functional versatility.
Ultimately, the work of Di Gaspare and collaborators marks a significant milestone in the journey to unlock the full potential of topological quantum materials in nonlinear optics. Their approach not only enriches our understanding of light-matter interactions at the quantum level but also charts a clear path toward transformative photonic technologies that harness the subtle, powerful interplay of symmetry, topology, and nanostructure engineering. In an era increasingly defined by information and energy efficiency, such innovations could shape the future landscape of both fundamental research and everyday technology.
Subject of Research: Nonlinear optical processes, specifically second and third harmonic generation, in topological insulator-based van der Waals metamaterials.
Article Title: Second and third harmonic generation in topological insulator-based van der Waals metamaterials.
Article References:
Di Gaspare, A., Ghayeb Zamharir, S., Knox, C. et al. Second and third harmonic generation in topological insulator-based van der Waals metamaterials. Light Sci Appl 14, 337 (2025). https://doi.org/10.1038/s41377-025-01847-5
Image Credits: AI Generated
DOI: https://doi.org/10.1038/s41377-025-01847-5
Tags: condensed matter physics advancementsharmonic generation in opticslight interactions with matternonlinear optical processesquantum technologies and topological materialssecond and third harmonic signalsspin-momentum locking in TIssurface states in topological materialsTopological insulatorstwo-dimensional heterostructuresultrafast photonic devicesvan der Waals metamaterials
