Abstract
Active optical media leading to interaction Hamiltonians of the form represent a crucial resource for quantum optical technology. In this paper, we address the characterization of those nonlinear media using quantum probes, as opposed to semiclassical ones. In particular, we investigate how squeezed probes may improve individual and joint estimation of the nonlinear coupling and of the nonlinearity order . Upon using tools from quantum estimation, we show that: (i) the two parameters are compatible, i.e., the may be jointly estimated without additional quantum noise; (ii) the use of squeezed probes improves precision at fixed overall energy of the probe; (iii) for low energy probes, squeezed vacuum represent the most convenient choice, whereas for increasing energy an optimal squeezing fraction may be determined; (iv) using optimized quantum probes, the scaling of the corresponding precision with energy improves, both for individual and joint estimation of the two parameters, compared to semiclassical coherent probes. We conclude that quantum probes represent a resource to enhance precision in the characterization of nonlinear media, and foresee potential applications with current technology.
Highlights
Accepted: 14 October 2021Squeezed states and entangled pairs of photons are crucial resources in current implementations of quantum technologies [1], including quantum enhanced sensing, quantum repeaters and the realization of quantum gates in several platforms
The quantum Fisher information (QFI) represents the ultimate bound on the precision among the set of all the possible measurements, in general described by a positive-operator valued measure (POVM)
We have addressed the use of squeezed states to improve precision in the characterization of nonlinear media
Summary
Squeezed states and entangled pairs of photons are crucial resources in current implementations of quantum technologies [1], including quantum enhanced sensing, quantum repeaters and the realization of quantum gates in several platforms. Our aim is to investigate how the precision of the estimation scales as a function of the average number of photons of the probe, and to assess the performance of different probing signals, with the goal of quantifying the improvement achievable by using nonclassical resources as squeezing. Upon using tools from quantum estimation theory [13,14], we are going to determine the optimal measurement to be performed at the output, and to evaluate the corresponding ultimate quantum limit to precision. We let the probe interact with the nonlinear medium, and we perform a measurement in order to extract information about the parameters we want to estimate.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
