Purification is a tool that allows to represent mixed quantum states as pure states on enlarged Hilbert spaces. A purification of a given state is not unique and its entanglement strongly depends on the particular choice made. Moreover, in one-dimensional systems, the amount of entanglement is linked to how efficiently the purified state can be represented using matrix-product states (MPS). We introduce an MPS based method that allows to find the minimally entangled representation by iteratively minimizing the second Rényi entropy. First, we consider the thermofield double purification and show that its entanglement can be strongly reduced especially at low temperatures. Second, we show that a slowdown of the entanglement growth following a...
We show that entanglement can always arise in the interaction of an arbitrarily large system in any ...
We show that entanglement can always arise in the interaction of an arbitrarily large system in any ...
We show how to simulate numerically the evolution of 1D quantum systems under dissipation as well as...
Purification is a tool that allows to represent mixed quantum states as pure states on enlarged Hilb...
The minimally entangled typical thermal states (METTS) are an ensemble of pure states, equivalent to...
Abstract Purification is a powerful technique in quantum physics whereby a mixed quantum state is ex...
We study thermal states of strongly interacting quantum spin chains and prove that those can be repr...
Quantum technologies exploiting bipartite entanglement could be made more efficient by using states ...
We prove that no physical map can provide a perfect purification of an unknown quantum state. Here, ...
Quantum technologies exploiting bipartite entanglement could be made more efficient by using states ...
A quantum state's entanglement across a bipartite cut can be quantified with entanglement entropy or...
We consider a system subject to a quantum optical master equation at finite temperature and study a ...
We present a general sufficiency condition for the presence of multipartite entanglement in thermal...
International audienceDespite being a well-established operational approach to quantify entanglement...
We show that entanglement can always arise in the interaction of an arbitrarily large system in any ...
We show that entanglement can always arise in the interaction of an arbitrarily large system in any ...
We show how to simulate numerically the evolution of 1D quantum systems under dissipation as well as...
Purification is a tool that allows to represent mixed quantum states as pure states on enlarged Hilb...
The minimally entangled typical thermal states (METTS) are an ensemble of pure states, equivalent to...
Abstract Purification is a powerful technique in quantum physics whereby a mixed quantum state is ex...
We study thermal states of strongly interacting quantum spin chains and prove that those can be repr...
Quantum technologies exploiting bipartite entanglement could be made more efficient by using states ...
We prove that no physical map can provide a perfect purification of an unknown quantum state. Here, ...
Quantum technologies exploiting bipartite entanglement could be made more efficient by using states ...
A quantum state's entanglement across a bipartite cut can be quantified with entanglement entropy or...
We consider a system subject to a quantum optical master equation at finite temperature and study a ...
We present a general sufficiency condition for the presence of multipartite entanglement in thermal...
International audienceDespite being a well-established operational approach to quantify entanglement...
We show that entanglement can always arise in the interaction of an arbitrarily large system in any ...
We show that entanglement can always arise in the interaction of an arbitrarily large system in any ...
We show how to simulate numerically the evolution of 1D quantum systems under dissipation as well as...