2 research outputs found
Extending the coherence time of spin defects in hBN enables advanced qubit control and quantum sensing
Spin defects in hexagonal Boron Nitride (hBN) attract increasing interest for
quantum technology since they represent optically-addressable qubits in a van
der Waals material. In particular, negatively-charged boron vacancy centers
() in hBN have shown promise as sensors of temperature, pressure, and
static magnetic fields. However, the short spin coherence time of this defect
currently limits its scope for quantum technology. Here, we apply dynamical
decoupling techniques to suppress magnetic noise and extend the spin coherence
time by nearly two orders of magnitude, approaching the fundamental
relaxation limit. Based on this improvement, we demonstrate advanced spin
control and a set of quantum sensing protocols to detect electromagnetic
signals in the MHz range with sub-Hz resolution. This work lays the foundation
for nanoscale sensing using spin defects in an exfoliable material and opens a
promising path to quantum sensors and quantum networks integrated into
ultra-thin structures
Extending the coherence of spin defects in hBN enables advanced qubit control and quantum sensing
Abstract Negatively-charged boron vacancy centers ( V B − ) in hexagonal Boron Nitride (hBN) are attracting increasing interest since they represent optically-addressable qubits in a van der Waals material. In particular, these spin defects have shown promise as sensors for temperature, pressure, and static magnetic fields. However, their short spin coherence time limits their scope for quantum technology. Here, we apply dynamical decoupling techniques to suppress magnetic noise and extend the spin coherence time by two orders of magnitude, approaching the fundamental T 1 relaxation limit. Based on this improvement, we demonstrate advanced spin control and a set of quantum sensing protocols to detect radiofrequency signals with sub-Hz resolution. The corresponding sensitivity is benchmarked against that of state-of-the-art NV-diamond quantum sensors. This work lays the foundation for nanoscale sensing using spin defects in an exfoliable material and opens a promising path to quantum sensors and quantum networks integrated into ultra-thin structures