APL Materials (Jan 2019)

Toward wafer-scale diamond nano- and quantum technologies

  • Richard Nelz,
  • Johannes Görlitz,
  • Dennis Herrmann,
  • Abdallah Slablab,
  • Michel Challier,
  • Mariusz Radtke,
  • Martin Fischer,
  • Stefan Gsell,
  • Matthias Schreck,
  • Christoph Becher,
  • Elke Neu

DOI
https://doi.org/10.1063/1.5067267
Journal volume & issue
Vol. 7, no. 1
pp. 011108 – 011108-5

Abstract

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We investigate native nitrogen vacancy (NV) and silicon vacancy (SiV) color centers in a commercially available, heteroepitaxial, wafer-sized, mm thick, single-crystal diamond. We observe single, native NV centers with a density of roughly 1 NV per μm3 and moderate coherence time (T2 = 5 μs) embedded in an ensemble of SiV centers. Using low temperature luminescence of SiV centers as a probe, we prove the high crystalline quality of the diamond especially close to the growth surface, consistent with a reduced dislocation density. Using ion implantation and plasma etching, we verify the possibility to fabricate nanostructures with shallow color centers rendering our material promising for fabrication of nanoscale sensing devices. As this diamond is available in wafer-sizes up to 100 mm, it offers the opportunity to up-scale diamond-based device fabrication.