The frontier of condensed matter physics has witnessed a groundbreaking advance with the successful optical control of integer and fractional Chern insulators (CIs and FCIs) in twisted bilayer MoTe₂ (tMoTe₂). This development represents a monumental leap in our ability to manipulate complex topological quantum states, which arise from the interplay of electron correlations and band topology. Researchers have demonstrated that by using circularly polarized light, they can finely tune the ferromagnetic polarization that underlies these exotic phases, thereby achieving dynamic and on-demand control over their topological character.
The significance of optical control in topological phases extends beyond fundamental physics; it hints at possibilities for next-generation quantum devices. Traditionally, tuning topological states—especially those involving strong electron-electron interactions—has required static methods, such as mechanical strain or electrostatic gating. Optical methods introduce unprecedented flexibility and speed, potentially enabling ultrafast control protocols that operate on timescales far shorter than conventional electronic approaches.
Underpinning this breakthrough is twisted bilayer MoTe₂, a van der Waals heterostructure where two layers of molybdenum ditelluride are stacked with a small rotational misalignment. This twisting leads to the emergence of flat electronic bands with nontrivial topological properties, hosting fractional Chern insulating states at zero magnetic field. Unlike conventional fractional quantum Hall states that rely on Landau levels created by strong magnetic fields, these FCIs arise purely from correlations within engineered bandstructures, making their control particularly appealing for practical quantum technologies.
In recent experiments, the team exploited the helicity of circularly polarized light to manipulate the system’s ferromagnetic order. At low excitation powers, circularly polarized optical pumping serves as a training protocol, nudging the system from a paramagnetic phase into a ferromagnetically polarized state with a well-defined Chern number. This process effectively “writes” a topological state through light-matter interactions, a capability that could be harnessed to program topological quantum bits or design energy-efficient spintronic devices.
More strikingly, when the optical excitation power is increased, the researchers observed direct switching of the ferromagnetic polarization at cryogenic temperatures well below the Curie temperature. This switching underscores the robustness of the optically induced magnetic states and demonstrates a reversible mechanism for toggling between states with differing topological invariants. Such reversible optical switching could be the foundation for new forms of topological memory where data is encoded into topological order rather than traditional electron charge or spin.
The mechanism behind these effects is linked to the valley-selective polarization of optically pumped holes within the tMoTe₂ band structure. The presence of an energy gap in the electronic spectrum, characteristic of the CI and FCI phases, enhances this valley polarization by selectively populating specific valleys in the Brillouin zone. This valley polarization couples directly to the spin and orbital degrees of freedom that define the ferromagnetic state, offering an elegant pathway for optical control over the system’s magnetism and topology.
Additionally, spatially resolved techniques revealed that this optical control can be localized, allowing patterning of ferromagnetic domains with distinct Chern numbers. This spatial precision facilitates the creation of interfaces hosting exotic topological edge states—quasiparticles whose properties can be finely engineered through light. With programmable patterning, scientists can conceive architectures where integer and fractionally quantized Hall domains coexist, opening the door to complex device functionalities that exploit topological order in real space.
Beyond the immediate implications in spintronics and quantum memory, the optical tunability demonstrated in these experiments signals a new paradigm in the study of nonequilibrium topological matter. Light not only serves as a passive probe but acts as an active agent for steering quantum phases, enabling experiments that were previously abstract theoretical constructs. This fosters an exciting synergy between Floquet engineering, many-body physics, and quantum materials research.
The work also raises intriguing possibilities for future explorations, including the coupling of Chern insulator domains to superconductors or magnetic substrates to explore hybrid quantum states. The precise control over ferromagnetism and topological order may facilitate the generation of non-Abelian quasiparticles or exotic fractionalized excitations that are promising candidates for fault-tolerant quantum computation.
Furthermore, the controllable interplay between optical helicity and magnetization broadens the horizon for developing optically addressable topological qubits, which could operate at elevated temperatures compared to traditional quantum Hall systems. With optimization, these optically controlled Chern insulators might enable scalable arrays of topological quantum bits that can be rapidly initialized and manipulated using well-established photonic techniques.
The research documented in a recent article published in Nature represents a milestone by Holtzmann, Li, Anderson, et al., in demonstrating that topological quantum many-body phases are not only theoretically fascinating but also experimentally malleable with light. Their rigorous experimentation and theoretical interpretations pave the way for harnessing topology in practical quantum technologies while deepening our understanding of driven quantum systems.
As the field progresses, the merging of optics and topology is destined to unlock novel material functionalities that marry the best of both worlds: the tunability and speed of photonics with the robustness and exotic physics of topological quantum matter. This confluence holds promise not only for fundamental discoveries but also for transformative advances in information technology, where energy-efficient, robust, and fast quantum devices become a reality.
Subject of Research: Optical manipulation of ferromagnetic polarization and topological quantum phases in twisted bilayer MoTe₂ leading to tunable integer and fractional Chern insulators.
Article Title: Optical control of integer and fractional Chern insulators.
Article References:
Holtzmann, W., Li, W., Anderson, E. et al. Optical control of integer and fractional Chern insulators. Nature 649, 1147–1152 (2026). https://doi.org/10.1038/s41586-025-09777-3
DOI: 10.1038/s41586-025-09777-3
Image Credits: AI Generated
Tags: dynamic control of topological characterelectron correlations and band topologyexotic phases in condensed matter systemsferromagnetic polarization controlflat electronic bands in twisted materialsfractional Chern insulators in twisted bilayer MoTe₂mechanical strain vs optical methodsnext-generation quantum devicesoptical tuning of Chern insulatorstopological quantum states manipulationultrafast optical methods in condensed matter physicsvan der Waals heterostructures for topological phases
