Architectures for lattice surgery-based surface code quantum computing under 3-dimensional nearest-neighbor connectivity

Efforts are being made to develop quantum processors beyond planar connectivity and quantum error correction codes suitable for 3-dimensional structures. In this study, we propose 3-dimensional architectures of logical data qubits and logical ancilla qubits based on surface codes using lattice surgery in situations where 3-dimensional nearest-neighbor connectivity between physical qubits is guaranteed. We also propose a method for performing CNOT operations on the proposed architecture. We present a physical qubit structure that stacks 2-dimensional physical qubit layers and adds several additional physical qubits for lattice surgery between adjacent layers. Our design permits the fast transversal application of CNOT operations between logical qubits in a nearest-neighbor relationship on adjacent layers, which is three times faster than the speed of standard lattice surgery CNOTs. Our design also permits the performance of CNOT operations between logical qubits that are far from each other using fast SWAP operations with transversal CNOT and lattice surgery. To demonstrate the advantages of our architecture, we present the required number of qubits and time for benchmark circuits on the proposed architecture and compare the required qubits and time on the checkerboard architecture and row-type architecture which are a 2-dimensional architectures to show the advantages of our architecture.