Quantum Sensing with Nanoelectronics: Fisher Information for an Adiabatic Perturbation

Quantum systems used for metrology can offer enhanced precision over their classical counterparts. The design of quantum sensors can be optimized by maximizing the quantum Fisher information (QFI), which characterizes the precision of parameter estimation for an ideal measurement. Here we consider the response of a quantum system as a means to estimate the strength of an external perturbation that has been switched on slowly. General expressions for the QFI are derived, which also hold for interacting many-body systems in the thermodynamic limit at finite temperatures, and can be related to linear-response transport coefficients. For quantum dot nanoelectronics devices, we show that electron interactions can lead to exponential scaling of the QFI with system size, highlighting that quantum resources can be utilized in the full Fock space. The precision estimation of voltages and fields can also be achieved by practical global measurements, such as the electric current, making quantum circuits good candidates for metrological applications.