Symmetry-protected adiabatic quantum metrology.

The aim of quantum metrology is to estimate target parameters as precisely as possible. In this paper, we propose a protocol for quantum metrology based on symmetry-protected adiabatic transformation. We introduce a ferromagnetic Ising model with a transverse field as a probe and consider the estimation of a longitudinal field. Without the transverse field, the ground state of the probe is given by the Greenberger-Horne-Zeilinger state, and thus the Heisenberg limit estimation of the longitudinal field can be achieved through parity measurement. We find that information of the longitudinal field encoded on parity can be mapped to global magnetization by symmetry-protected adiabatic transformation, i.e., parity measurement can be replaced with global magnetization measurement. Our scheme requires neither accurate control of individual qubits nor that of interaction strength.