The NV center-based measurement techniques introduced in this thesis offer promising new measurement tools that could have large impacts in other research areas, such as quantum computing. For example, the electric field sensing technique could be used to explore the source of surface charge noise in materials used in superconducting qubits or semiconductor quantum dots. The technique using single NV centers to probe charge dynamics also expands our understanding of the charge states of silicon vacancy centers in diamond, which are promising defects for quantum networks. Moreover, the demonstrated new super-resolution technique provides a gateway for other research groups to easily achieve super-resolution in their work and advance their research.
Events
The NV center-based measurement techniques introduced in this thesis offer promising new measurement tools that could have large impacts in other research areas, such as quantum computing. For example, the electric field sensing technique could be used to explore the source of surface charge noise in materials used in superconducting qubits or semiconductor quantum dots. The technique using single NV centers to probe charge dynamics also expands our understanding of the charge states of silicon vacancy centers in diamond, which are promising defects for quantum networks. Moreover, the demonstrated new super-resolution technique provides a gateway for other research groups to easily achieve super-resolution in their work and advance their research.