Data underlying the dissertation "Quantum sensing in diamond and silicon carbide: mapping spins and taming charges"

Solid-state defects in diamond and silicon carbide have emerged as a promising platform for exploring various quantum technologies, such as distributed quantum computing, quantum simulations of many-body physics, and nano-scale nuclear magnetic resonance. The noise environment surrounding such defects, consisting of magnetic and electrical impurities, directly impacts the spin and optical coherence, posing a key challenge for advancing quantum technologies. Systematic study of these spins and charges is crucial for mitigating their noise contribution. In some cases, establishing control over the environment can even convert it into a resource, to be used for storing, or processing (quantum) information. In this thesis, we develop experimental and analytical tools that enable a more detailed study of the defect spin and charge environment, and can be exploited to manipulate its microscopic configuration. <br>Data for Chapter 2 is available in JSON format here.Data for Chapter 3 and Appendix A is available at: https://doi.org/<strong>10.4121/9d3f41e9-ddcd-4153-8508-2a9a9d5ea654</strong>Data for Chapter 4 and Appendix B is available at: https://doi.org/10.4121/643ed69d-ced0-4d45-86b3-534a5b79c605Data for Chapter 5 and Appendix C is available at: https://doi.org/10.4121/aba1cc84-0aea-4cdc-93ca-68b0db38bd81

金刚石与碳化硅中的固态缺陷（solid-state defects）已成为探索各类量子技术的极具前景的研究平台，涵盖分布式量子计算、多体物理量子模拟与纳米级核磁共振（nuclear magnetic resonance）等方向。此类缺陷周边的噪声环境由磁性与电性杂质构成，会直接影响自旋（spin）与光学相干性（optical coherence），成为推进量子技术发展的关键挑战。对这些自旋与电荷体系开展系统性研究，对于削弱其噪声贡献至关重要。在部分场景中，实现对环境的精准调控甚至可将其转化为可用于存储或处理（量子）信息的资源。本论文开发了一系列实验与分析工具，可实现对缺陷自旋与电荷环境的更精细化研究，并可用于操控其微观构型。 第2章相关数据可在此处以JSON格式获取。 第3章与附录A的相关数据可通过以下链接获取：https://doi.org/10.4121/9d3f41e9-ddcd-4153-8508-2a9a9d5ea654 第4章与附录B的相关数据可通过以下链接获取：https://doi.org/10.4121/643ed69d-ced0-4d45-86b3-534a5b79c605 第5章与附录C的相关数据可通过以下链接获取：https://doi.org/10.4121/aba1cc84-0aea-4cdc-93ca-68b0db38bd81