Fault-Tolerant Optical Quantum Computation using 3D Hybrid Cluster States (2503.14988v2)

Abstract: Hybridizing different physical systems or degrees of freedom offers significant advantages for realizing practical, universal, scalable, and fault-tolerant quantum computation (FTQC). Here, we propose optical FTQC schemes with low squeezing thresholds by leveraging the strengths of both discrete-variable (DV) and continuous-variable (CV) systems while utilizing frequency, time, and orbital angular momentum degrees of freedom. First, we design an optical entanglement generator (OEG) capable of producing various types of entangled pairs, including cluster pairs, hybrid entangled pairs, and GKP Bell pairs, which can be flexibly chosen by adjusting the measurement basis. Additionally, the OEG features extra ports for directly inputting (outputting) data (result) states via quantum teleportation, eliminating the need for optical switches. Secondly, large-scale one-dimensional, two-dimensional, and three-dimensional (3D) hybrid cluster states, composed of DV Gottesman-Kitaev-Preskill (GKP) qubits and CV squeezed states, are deterministically generated using the entangled pairs passed through a time-delay system. Moreover, we optimize the surface-GKP code to further reduce logical errors during the stabilizer measurements in the surface code. By combining the 3D cubic hybrid cluster state with the modified surface-GKP code and accounting for full circuit-level noise, FTQC is achieved with a squeezing threshold of 10 dB. Moreover, our method can also generate a 3D macronode Raussendorf-Harrington-Goyal (RHG) cluster state, facilitating an alternative FTQC scheme via the RHG-GKP code. Our work provides a viable pathway toward future optical FTQC architectures.