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Beilstein J. Nanotechnol. 2012, 3, 895–908, doi:10.3762/bjnano.3.100
Figure 1: (a) Scanning electron micrograph of a mica mask. High aspect ratio channels were created by bombard...
Figure 2: Nonlinear optical microscopy of implanted color centers by using ground-state-depletion microscopy ...
Figure 3: Fluorescence spectra of the nitrogen–vacancy defect in diamond. The upper curve shows the spectrum ...
Figure 4: Plasmonic resonator geometries, field I and current q for (a) half-wave antenna, (b) bow tie and cr...
Figure 5: Enhancement of the collection efficiency with a hemispherical solid immersion lens (SIL). (a) Reduc...
Figure 6: Macroscopic solid immersion lens [10]. (a) Photograph of a single crystalline diamond hemisphere. (b) C...
Figure 7: Fabrication of a microscopic diamond hemisphere by focused ion beam milling. (a) Grid of FIB marker...
Figure 8: (a) Scanning electron microscopy (SEM) image of a micropillar resonator with embedded diamond nanoc...
Figure 9: (a) Normalized intensity autocorrelation function g(2)(τ) from a micropillar cavity of 1.6 µm diame...
Figure 10: View into the MWPECVD reactor during growth of a single-crystalline diamond layer.
Figure 11: (a) Optical emission spectroscopy: observed nickel emission in the MWPECVD plasma during diamond gr...
Figure 12: (a) SIMS depth profile of nickel-doped single-crystal diamond layer. The intensity of the two “mark...
Figure 13: Cathodoluminescence spectra measured at a temperature of 5 K on a nickel-doped single-crystal diamo...
Figure 14: (a–c) Room-temperature PL mapping excited at a wavelength of 660 nm on (111) diamond layers grown b...
Figure 15: (a) As-grown nanodiamond particles on a silicon substrate. (b) Confocal photoluminescence mapping (...