We develop an architecture for measurement-based quantum computing using photonic quantum emitters. The architecture exploits spin-photon entanglement as resource states and standard Bell measurements of photons for fusing them into a large spin-qubit cluster state. The scheme is tailored to emitters with limited memory capabilities since it only uses an initial non-adaptive (ballistic) fusion process to construct a fully percolated graph state of multiple emitters. By exploring various geometrical constructions for fusing entangled photons from deterministic emitters, we improve the photon loss tolerance significantly compared to similar all-photonic schemes.

中文翻译：

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使用量子发射器进行量子计算的丢失容忍架构

我们开发了一种使用光子量子发射器进行基于测量的量子计算的架构。该架构利用自旋光子纠缠作为资源状态和光子的标准贝尔测量，将它们融合成一个大型自旋量子位簇状态。该方案是为具有有限存储能力的发射器量身定制的，因为它仅使用初始非自适应（弹道）融合过程来构建多个发射器的完全渗透图状态。通过探索用于融合来自确定性发射器的纠缠光子的各种几何结构，与类似的全光子方案相比，我们显着提高了光子损失容限。