Quantum computing promises fault tolerance, but only if information is protected against the relentless local errors that plague today’s devices. A leading route uses topologically ordered phases of matter, where quantum states are stored globally in a way that local noise cannot easily corrupt. For decades, two complementary strategies have defined the field: encoding in ground-state manifolds, or encoding in excitations such as anyons. The toric code captures the first idea but lacks an intrinsic, universal gate set, leaving a major gap between protection and computation.
Topological quantum computation offers a different vision: implement logic by braiding non-Abelian anyons, whose exchanges enact transformations on a degenerate Hilbert space. Yet for the simplest non-Abelian extensions of the toric code, braiding alone has long been known to be insufficient for universal quantum computation. The missing ingredient is not more braiding, but an additional primitive that leverages the internal structure of anyons—namely, fusion.
In a new hardware demonstration, researchers show that anyon fusion, when combined with braiding, can supply the missing universality. Working with a quantum double model based on the smallest non-Abelian group, (S_3), they focus on encoding information in the global fusion space of non-Abelian anyons. Instead of relying solely on exchange operations, they treat fusion as an active computational step, enabling a richer set of logical transformations.
The team prepares a 54-qubit ground state of the (S_3) quantum double on Quantinuum’s H2 processor. This matters because creating a specific topological phase is not just a theoretical construction—it requires carefully engineering the many-body constraints that define the fusion rules and anyonic structure. Their experiment operationalizes those constraints so that logical degrees of freedom live in the anyon fusion space.
By integrating braiding with fusion operations, the researchers implement a universal topological gate set. They also perform read-out in the same topological framework, ensuring that measurement respects the global nature of the encoded information. Crucially, they validate the computational power by topologically preparing a magic state, an essential resource for achieving universal quantum computation under fault-tolerant schemes.
Taken together, the work argues that minimally non-Abelian topological states can be both scalably preparable and computationally powerful—if fusion is used as a primitive rather than treated as a passive property. That shift reframes what is required for universality: not just non-Abelian statistics, but the ability to control how anyons combine.
Beyond this specific model, the results suggest broader pathways for harnessing the intrinsic properties of quantum matter. If fusion-controlled universality can be extended to other quantum double phases and hardware platforms, topological codes may become not only robust memories but practical computational substrates. For viral science news, the headline is simple: the path to universal, fault-tolerant quantum computing just gained a crucial new lever—anyon fusion on real hardware.
Subject of Research: Topological quantum computation using non-Abelian anyons; universality via braiding and fusion
Article Title: Universal gates from braiding and fusing anyons on quantum hardware
Article References: Lo, C.F.B., Lyons, A., Gresh, D. et al. Universal gates from braiding and fusing anyons on quantum hardware. Nature 655, 591–597 (2026). https://doi.org/10.1038/s41586-026-10709-y
Image Credits: AI Generated
DOI: 10.1038/s41586-026-10709-y
Keywords: topological quantum computation; non-Abelian anyons; fusion and braiding; quantum double; (S_3); magic state; fault tolerance








