Symmetry-Protected Quantum Computing using Metamaterials

Neil F. Johnson, Ferney J. Rodriguez, Luis Quiroga

arXiv:2606.0025478.8h-index: 5

AI Analysis

For quantum computing researchers, this proposes a generic architecture but remains theoretical with no experimental validation.

The paper proposes a quantum computing architecture combining symmetry protection, twisted-light control, and metamaterial nanofocusing, claiming it applies to any system with parabolic confinement. No concrete performance numbers are provided.

We propose a new architecture for practical quantum computing that combines three established principles: symmetry protection of relative-motion qubits via the generalized Kohn theorem, control via twisted-light orbital angular momentum, and metamaterial nanofocusing (e.g. using Weyl-semimetal plasmonics). Crucially, the core mechanism is generic: it applies to any current or future quantum computing system involving parabolic confinement, including cold atoms, ions, and semiconductor dots.

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