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Artificial Gauge Fields and Dimensions in a Polariton Hofstadter Ladder

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arxiv 2506.13521 v1 pith:ADLS6KTS submitted 2025-06-16 physics.optics physics.app-ph

Artificial Gauge Fields and Dimensions in a Polariton Hofstadter Ladder

classification physics.optics physics.app-ph
keywords fieldstopologicalartificialgaugemagneticparticlespolaritoncareful
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Artificial gauge fields allow uncharged particles to mimic the behavior of charged particles subjected to magnetic fields, providing a powerful platform for exploring topological physics. Neutral particles, like photons, are typically unaffected by real magnetic fields. However, it is possible to introduce artificial gauge fields that control the effective dynamics of these neutral particles. Topological exciton-polariton lasers have attracted considerable interest, in part due to the wide range of tunable system parameters, but often require strong magnetic fields to realise propagating topological edge states. Here we show, that by using an artificial gauge field the topological Hall effect in a micron-scale micropillar chain is experimentally realised, exploiting the circular polarisation of polaritons as an artificial dimension. By careful rotational alignment of elliptical micropillars, we introduce an effective plaquette phase that induces strictly polarisation-dependent edge-state propagation, demonstrating non-reciprocal transport of the polariton pseudospins. Our results demonstrate that the dimensionality limitation of topological interface states as well as requirements for strong external magnetic fields in coupled topological laser arrays can be overcome by utilizing polarisation effects and careful engineering of the potential landscape. Our results open new ways towards the implementation of topological polariton lattices and related optically active devices with additional artificial dimension.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Spin-momentum locking of polariton edge states in honeycomb lattices

    cond-mat.mes-hall 2026-07 conditional novelty 6.0

    Zigzag edge states in exciton-polariton honeycomb lattices exhibit intrinsic spin-momentum locking from TE–TM splitting, enabling helicity-controlled selective lasing of chiral edge modes without magnetic fields.

  2. Spin-polarized lasing in a photonic lattice

    physics.optics 2026-05 unverdicted novelty 5.0

    Spin-polarized photon lasing with pump-following circular polarization and extended coherence is demonstrated in a two-dimensional photonic lattice VCSEL.