Ultra-sensitive magnetic sensor based on 3-dimensional rotation induced Berry phase

High-sensitivity magnetometers play a crucial role in various domains, including fundamental physics, biomedical imaging, and navigation. Levitated diamonds containing nitrogen-vacancy (NV) centers exhibit significant potential for magnetic sensing due to their high mechanical quality (Q) factor and long spin coherence time. However, previous studies have predominantly focused on electron spin-based measurements of alternating current (AC) magnetic fields. In this letter, we propose a novel approach for direct current (DC) magnetic field measurement based on the Berry phase generated by three-dimensional rotation. We analyze the adiabatic evolution of the 14N nuclear spin inside a levitated 3D rotating diamond with frequencies around MHz. Our finding reveals that the Berry phase exhibits high sensitivity to external parameters near rotation induced nuclear spin resonance. Using this mechanism, we theoretically demonstrate that the static magnetic field sensitivity can reach 10^(-7) T/Hz^(1/2)/N^(1/2) for 14N nuclear spins under the current experimental conditions.