Efficient approach for quantum sensing field gradients with trapped ions

We introduce quantum sensing protocol for detection spatially varying fields by using two coupled harmonic oscillators as a quantum probe. We discuss a physical implementation of the sensing technique with two trapped ions coupled via Coulomb mediated phonon hopping. Our method relies on using the coupling between the localized ion oscillations and the internal states of the trapped ions which allows to measure spatially varying electric and magnetic fields. First we discuss an adiabatic sensing technique which is capable to detect a very small force difference simply by measuring the ion spin population. We also show that the adiabatic method can be used for detection magnetic field gradient which is independent of the magnetic offset. Second, we show that the strong spin phonon coupling could leads to improve sensitivity to force as well as to phase estimations. We quantify the sensitivity in terms of quantum Fisher information and show that it diverges by approaching the critical coupling.