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Q: Fachverband Quantenoptik und Photonik

Q 33: Cavity QED, QED, and Spin-Boson Systems I

Q 33.5: Talk

Wednesday, March 4, 2026, 15:30–15:45, P 4

Cavity-Enhanced Spin-Photon Interface for Single Tin-Vacancy Centers in Diamond — •Andras Lauko¹, Kerim Köster¹, Julia Heupel², Philipp Grasshoff², Vladislav Bushmakin³, Michael Kieschnick⁴, Michael Förg⁵, Thomas Hümmer⁵, Cyril Popov², Jörg Wrachtrup³, Jan Meijer⁴, and David Hunger¹ — ¹Karlsruher Institut für Technologie — ²Universität Kassel — ³Universität Stuttgart — ⁴Universität Leipzig — ⁵Qlibri GmbH

Building a long-distance quantum network is one of the big challenges in the field of quantum communication, which requires an efficient photonic interface for coherent spins.

Tin-vacancy centers in diamond are a rising candidate among color centers in diamond, enabling higher operating temperatures than silicon-vacancy centers and being less prone to charge noise relative to nitrogen-vacancy centers.

In our experiment, we integrate a diamond membrane into an open access fiber-based Fabry-Perot microcavity to attain emission enhancement in a single well-collectable mode. We present our fully tunable, cryogenic cavity platform operating in a table-top dilution cryostat, and we achieve a cavity-length stability up to one picometer rms. The platform also allows for integration of a superconducting DC magnet and microwave antenna for spin manipulation.

We observe coupling between single tin-vacancy centers and a cavity mode through Purcell-enhanced emission, and cavity-enhanced extinction in transmission.

Keywords: Color center; Tin-Vacancy; SnV; Cavity