We show a surprising link between experimental setups to realize high-dimensional multipartite quantum states and graph theory. In these setups, the paths of photons are identified such that the photon-source information is never created. We find that each of these setups corresponds to an undirected graph, and every undirected graph corresponds to an experimental setup. Every term in the emerging quantum superposition corresponds to a perfect matching in the graph. Calculating the final quantum state is in the #P-complete complexity class, thus it cannot be done efficiently. To strengthen the link further, theorems from graph theory-such as Hall's marriage problem-are rephrased in the language of pair creation in quantum experiments. We sh...
AbstractIt is demonstrated that the recently developed technique of delocalized single photon additi...
We propose a scheme for efficient construction of graph states using realistic linear optics, imperf...
Quantum networks are composed of nodes which can send and receive quantum states by exchanging photo...
We present an approach to describe state-of-the-art photonic quantum experiments using graph theory....
Quantum entanglement plays an important role in quantum information processes, such as quantum compu...
We introduce the concept of hypergraphs to describe quantum optical experiments with probabilistic m...
Graph states are special kinds of multipartite entangled states that correspond to mathematical grap...
We state a number of related questions on the structure of perfect matchings. Those questions are in...
Given a suitably large and well connected (complex) graph state, any quantum algorithm can be implem...
Quantum information processing is the field of science where the underlying principles of quantum me...
Graph states are versatile resources for quantum computation and quantum-enhanced measurement. Their...
The connection between certain entangled states and graphs has been heavily studied in the context o...
Quantum networks are natural scenarios for the communication of information among distributed partie...
Entangled quantum states are remarkably rich resources for communication and computation. Today, we ...
We present the general Hardy-like quantum pigeonhole paradoxes for \textit{n}-particle states, and f...
AbstractIt is demonstrated that the recently developed technique of delocalized single photon additi...
We propose a scheme for efficient construction of graph states using realistic linear optics, imperf...
Quantum networks are composed of nodes which can send and receive quantum states by exchanging photo...
We present an approach to describe state-of-the-art photonic quantum experiments using graph theory....
Quantum entanglement plays an important role in quantum information processes, such as quantum compu...
We introduce the concept of hypergraphs to describe quantum optical experiments with probabilistic m...
Graph states are special kinds of multipartite entangled states that correspond to mathematical grap...
We state a number of related questions on the structure of perfect matchings. Those questions are in...
Given a suitably large and well connected (complex) graph state, any quantum algorithm can be implem...
Quantum information processing is the field of science where the underlying principles of quantum me...
Graph states are versatile resources for quantum computation and quantum-enhanced measurement. Their...
The connection between certain entangled states and graphs has been heavily studied in the context o...
Quantum networks are natural scenarios for the communication of information among distributed partie...
Entangled quantum states are remarkably rich resources for communication and computation. Today, we ...
We present the general Hardy-like quantum pigeonhole paradoxes for \textit{n}-particle states, and f...
AbstractIt is demonstrated that the recently developed technique of delocalized single photon additi...
We propose a scheme for efficient construction of graph states using realistic linear optics, imperf...
Quantum networks are composed of nodes which can send and receive quantum states by exchanging photo...