Distributed quantum computing links several QPUs so that they function together as a single, larger machine. The motivation is that monolithic scaling runs into hard engineering ceilings: control wiring density, dilution refrigerator cooling power, crosstalk between neighbouring qubits, and fabrication yield all worsen as a single chip grows, so at some point adding modules becomes easier than adding qubits to one die. Operations that span nodes are implemented using shared entanglement rather than physical wires — a pre-distributed entangled pair plus classical communication lets you teleport a qubit's state between nodes, or apply a teleportation-based two-qubit gate across the boundary without ever moving the data qubit itself. The central constraint is the interconnect: generating remote entanglement is currently far slower and far lower in fidelity than an on-chip gate, often by several orders of magnitude, so the link rather than the processor becomes the bottleneck and every cross-node operation is expensive in both time and error budget. This remains an active research direction with small proof-of-principle demonstrations, not a deployed capability.
Términos relacionados
Quantum Network
HardwareA system that links separate quantum processors by distributing entanglement between them, usually carried by photons.
Entrelazamiento
FundamentalsUna correlación cuántica entre dos o más qubits en la que sus estados están vinculados independientemente de la distancia.
QPU
HardwareQuantum Processing Unit (unidad de procesamiento cuántico): el chip de hardware físico que ejecuta circuitos cuánticos.
Qubit Lógico
HardwareUn qubit con corrección de errores codificado a través de muchos qubits físicos: la unidad de cálculo en los ordenadores cuánticos tolerantes a fallos.