Description
Additional datasets and Python software for analysis and plotting of the data presented in the dissertation. The dissertation contains experiments of diamond color centers coupled to open microcavities in the context of quantum networks. Experiments are performed in a quantum optics laboratory.
Here are stored the datasets and plot scripts for Chapter 3 (Background: Optical Background: Optical Cavities for Color Centers in Diamond),
together with additional data for Chapter 4 (Laser-cut Patterned, Micrometer-thin Diamond Membranes with Coherent Color Centers for Open Microcavities).
Datasets underlying the other Chapters can be found in (direct links are under References):
Chapter 4:
Laser-cut Patterned, Micrometer-thin Diamond Membranes with Coherent Color Centers for Open Microcavities
Reference: https://doi.org/10.4121/a8e32e27-5a91-4a4a-abfc-e5bd884317ae
Chapter 5:
A Low-Temperature Tunable Microcavity featuring High Passive Stability and Microwave Integration
Reference: https://doi.org/10.4121/451152e2-a4d4-4e42-96e0-4147afb1e45c
Chapter 6:
Coherent Coupling of a Diamond Tin-Vacancy Center to a Tunable Open Microcavity
Reference: https://doi.org/10.4121/421a26ac-4e92-411f-bb0a-5e6af21cf426
Chapter 7:
Spin-Photon Correlations from a Purcell-enhanced Diamond Nitrogen-Vacancy Center Coupled to an Open Microcavity
Reference: https://doi.org/10.4121/6f8031ae-dd61-4b4f-adf4-d20bc88ed9ac
and Chapter 8 (Conclusions and Outlook)
Here are stored the datasets and plot scripts for Chapter 3 (Background: Optical Background: Optical Cavities for Color Centers in Diamond),
together with additional data for Chapter 4 (Laser-cut Patterned, Micrometer-thin Diamond Membranes with Coherent Color Centers for Open Microcavities).
Datasets underlying the other Chapters can be found in (direct links are under References):
Chapter 4:
Laser-cut Patterned, Micrometer-thin Diamond Membranes with Coherent Color Centers for Open Microcavities
Reference: https://doi.org/10.4121/a8e32e27-5a91-4a4a-abfc-e5bd884317ae
Chapter 5:
A Low-Temperature Tunable Microcavity featuring High Passive Stability and Microwave Integration
Reference: https://doi.org/10.4121/451152e2-a4d4-4e42-96e0-4147afb1e45c
Chapter 6:
Coherent Coupling of a Diamond Tin-Vacancy Center to a Tunable Open Microcavity
Reference: https://doi.org/10.4121/421a26ac-4e92-411f-bb0a-5e6af21cf426
Chapter 7:
Spin-Photon Correlations from a Purcell-enhanced Diamond Nitrogen-Vacancy Center Coupled to an Open Microcavity
Reference: https://doi.org/10.4121/6f8031ae-dd61-4b4f-adf4-d20bc88ed9ac
and Chapter 8 (Conclusions and Outlook)
| Date made available | 19 Nov 2025 |
|---|---|
| Publisher | TU Delft - 4TU.ResearchData |
| Temporal coverage | 2022 - 2025 |
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Good Vibrations: A Microcavity-based Diamond Spin-Photon Interface for Quantum Networking
Herrmann, Y. S., 2025, 261 p.Research output: Thesis › Dissertation (TU Delft)
Open AccessFile35 Downloads (Pure) -
Laser-cut patterned, micrometer-thin diamond membranes with coherent color centers for open microcavities
Herrmann, Y., Brevoord, J. M., Fischer, J., Scheijen, S., Sauerzapf, C., Codreanu, N., Wienhoven, L. G. C., van der Graaf, Y. M. Q., Wolfs, C. F. J., Méjard, R., Ruf, M., de Jong, N. & Hanson, R., 2025, In: Materials for Quantum Technology. 5, 3, 035001.Research output: Contribution to journal › Article › Scientific › peer-review
Open AccessFile1 Downloads (Pure) -
Spin-photon correlations from a Purcell-enhanced diamond nitrogen-vacancy center coupled to an open microcavity
Fischer, J., Herrmann, Y., Wolfs, C. F. J., Scheijen, S., Ruf, M. & Hanson, R., 2025, In: Nature Communications. 16, 1, 9 p., 11680.Research output: Contribution to journal › Article › Scientific › peer-review
Open AccessFile
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