Add to ORKGA central feature of quantum metrology is the possibility of Heisenberg scaling, a quadratic improvement over the limits of classical statistics. This scaling, however, is notoriously fragile to noise. While for some noise types it can be restored through error correction, for other important types, such as dephasing, the Heisenberg scaling appears to be irremediably lost. Here we show that this limitation can sometimes be lifted if the experimenter has the ability to probe physical processes in a coherent superposition of alternative configurations. As a concrete example, we consider the problem of phase estimation in the presence of a random phase kick, which in normal conditions is known to prevent the Heisenberg scaling. We provide a pa...
We address the problem of distributed quantum metrology with a single squeezed-vacuum source by usin...
We address the problem of distributed quantum metrology with a single squeezed-vacuum source by usin...
We study how useful random states are for quantum metrology, i.e., whether they surpass the classica...
We establish general limits on how precise a parameter, e.g. frequency or the strength of a magnetic...
We propose a measurement setup reaching Heisenberg scaling precision for the estimation of any distr...
We propose a measurement setup reaching a Heisenberg scaling precision for the estimation of any dis...
We propose a measurement setup reaching Heisenberg scaling precision for the estimation of any distr...
We address the question of whether the super-Heisenberg scaling for quantum estimation is indeed rea...
We consider the estimation of an arbitrary parameter φ, such as the temperature or a magnetic field,...
We consider the estimation of an arbitrary parameter φ, such as the temperature or a magnetic field,...
We discuss the Heisenberg limit in the multiparameter metrology within two different paradigms -- th...
We study quantum frequency estimation for $N$ qubits subjected to independent Markovian noise, via s...
We consider quantum metrology in noisy environments, where the effect of noise and decoherence limit...
We study quantum frequency estimation for NN qubits subjected to independent Markovian noise, vi...
We derive fundamental bounds on the maximal achievable precision in multiparameter noisy quantum met...
We address the problem of distributed quantum metrology with a single squeezed-vacuum source by usin...
We address the problem of distributed quantum metrology with a single squeezed-vacuum source by usin...
We study how useful random states are for quantum metrology, i.e., whether they surpass the classica...
We establish general limits on how precise a parameter, e.g. frequency or the strength of a magnetic...
We propose a measurement setup reaching Heisenberg scaling precision for the estimation of any distr...
We propose a measurement setup reaching a Heisenberg scaling precision for the estimation of any dis...
We propose a measurement setup reaching Heisenberg scaling precision for the estimation of any distr...
We address the question of whether the super-Heisenberg scaling for quantum estimation is indeed rea...
We consider the estimation of an arbitrary parameter φ, such as the temperature or a magnetic field,...
We consider the estimation of an arbitrary parameter φ, such as the temperature or a magnetic field,...
We discuss the Heisenberg limit in the multiparameter metrology within two different paradigms -- th...
We study quantum frequency estimation for $N$ qubits subjected to independent Markovian noise, via s...
We consider quantum metrology in noisy environments, where the effect of noise and decoherence limit...
We study quantum frequency estimation for NN qubits subjected to independent Markovian noise, vi...
We derive fundamental bounds on the maximal achievable precision in multiparameter noisy quantum met...
We address the problem of distributed quantum metrology with a single squeezed-vacuum source by usin...
We address the problem of distributed quantum metrology with a single squeezed-vacuum source by usin...
We study how useful random states are for quantum metrology, i.e., whether they surpass the classica...