We propose a scheme for efficient construction of graph states using realistic linear optics, imperfect photon source and single-photon detectors. For any many-body entanglement represented by tree graph states, we prove that the overall preparation and detection efficiency scales only polynomially with the size of the graph, no matter how small the efficiencies for the photon source and the detectors
We introduce plaquette projected entangled-pair states, a class of states in a lattice that can be g...
Quantum information processing is the field of science where the underlying principles of quantum me...
We study the operation of linear optics schemes for entanglement distribution based on nonlocal phot...
Entanglement is a powerful concept with an enormous potential for scientific and technological advan...
Since linear-optical two-photon gates are inherently probabilistic, measurement-based implementation...
Given a suitably large and well connected (complex) graph state, any quantum algorithm can be implem...
We present a scheme for rapidly entangling matter qubits in order to create graph states for one-way...
Graph states are special kinds of multipartite entangled states that correspond to mathematical grap...
Graph states are versatile resources for quantum computation and quantum-enhanced measurement. Their...
Quantum information technology promises to offer incredible advantages over current digital systems,...
Quantum entanglement plays an important role in quantum information processes, such as quantum compu...
A method to generate maximally path-entangled photon-number states was established. It was shown tha...
Photonic cluster states are a crucial resource for optical quantum computing. Recently a quantum dot...
This work was supported by the National Natural Science Foundation of China (Grants No. 11575174, No...
Large-photon-number path entanglement is an important resource for enhanced precision measurements a...
We introduce plaquette projected entangled-pair states, a class of states in a lattice that can be g...
Quantum information processing is the field of science where the underlying principles of quantum me...
We study the operation of linear optics schemes for entanglement distribution based on nonlocal phot...
Entanglement is a powerful concept with an enormous potential for scientific and technological advan...
Since linear-optical two-photon gates are inherently probabilistic, measurement-based implementation...
Given a suitably large and well connected (complex) graph state, any quantum algorithm can be implem...
We present a scheme for rapidly entangling matter qubits in order to create graph states for one-way...
Graph states are special kinds of multipartite entangled states that correspond to mathematical grap...
Graph states are versatile resources for quantum computation and quantum-enhanced measurement. Their...
Quantum information technology promises to offer incredible advantages over current digital systems,...
Quantum entanglement plays an important role in quantum information processes, such as quantum compu...
A method to generate maximally path-entangled photon-number states was established. It was shown tha...
Photonic cluster states are a crucial resource for optical quantum computing. Recently a quantum dot...
This work was supported by the National Natural Science Foundation of China (Grants No. 11575174, No...
Large-photon-number path entanglement is an important resource for enhanced precision measurements a...
We introduce plaquette projected entangled-pair states, a class of states in a lattice that can be g...
Quantum information processing is the field of science where the underlying principles of quantum me...
We study the operation of linear optics schemes for entanglement distribution based on nonlocal phot...