Your search keyword '"Ganzhorn, Marc"' showing total 2 results

1. Fabrication of all diamond scanning probes for nanoscale magnetometry.

Author

Appel, Patrick, Neu, Elke, Ganzhorn, Marc, Barfuss, Arne, Batzer, Marietta, Gratz, Micha, Tschöpe, Andreas, and Maletinsky, Patrick

Subjects

ELECTRON spin, MAGNETIC fields, SINGLE crystals, ATOMIC force microscopy, DIAMONDS, NANORODS

Abstract

The electronic spin of the nitrogen vacancy (NV) center in diamond forms an atomically sized, highly sensitive sensor for magnetic fields. To harness the full potential of individual NV centers for sensing with high sensitivity and nanoscale spatial resolution, NV centers have to be incorporated into scanning probe structures enabling controlled scanning in close proximity to the sample surface. Here, we present an optimized procedure to fabricate single-crystal, all-diamond scanning probes starting from commercially available diamond and show a highly efficient and robust approach for integrating these devices in a generic atomic force microscope. Our scanning probes consisting of a scanning nanopillar (200 nm diameter, 1–2 μm length) on a thin (<1 μm) cantilever structure enable efficient light extraction from diamond in combination with a high magnetic field sensitivity (ηAC ≈ 50 ± 20 nT/ √ Hz). As a first application of our scanning probes, we image the magnetic stray field of a single Ni nanorod. We show that this stray field can be approximated by a single dipole and estimate the NV-to-sample distance to a few tens of nanometer, which sets the achievable resolution of our scanning probes. [ABSTRACT FROM AUTHOR]

Published

2016

2. Photonic nano-structures on (111)-oriented diamond.

Author

Neu, Elke, Appel, Patrick, Ganzhorn, Marc, Miguel-Sánchez, Javier, Lesik, Margarita, Mille, Vianney, Jacques, Vincent, Tallaire, Alexandre, Achard, Jocelyn, and Maletinsky, Patrick

Subjects

NANOSTRUCTURES, CHEMICAL vapor deposition, SINGLE crystals, PHOTONIC crystals, SUBSTRATES (Materials science), FLUORESCENCE

Abstract

We demonstrate the fabrication of single-crystalline diamond nanopillars on a (111)-oriented chemical vapor deposited diamond substrate. This crystal orientation offers optimal coupling of nitrogen-vacancy (NV) center emission to the nanopillar mode and is thus advantageous over previous approaches. We characterize single native NV centers in these nanopillars and find one of the highest reported saturated fluorescence count rates in single crystalline diamond in excess of 106 counts per second. We show that our nano-fabrication procedure conserves the preferential alignment as well as the spin coherence of the NVs in our structures. Our results will enable a new generation of highly sensitive probes for NV magnetometry and pave the way toward photonic crystals with optimal orientation of the NV center's emission dipole. [ABSTRACT FROM AUTHOR]

Published

2014