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howto:diamond_nv_centers

Diamond NV Centers

Basics

see also Nitrogen-vacancy center

Figure1: Model of the nitrogene vacancy in the diamond lattice

Excitation

  • wavelength 532nm
  • excitation power should be 100 µW or above

Emission

Figure 3 shows the emission spectra of a NV-center. The pronounced Peak at 637nm is the zero-phonon line of the diamond lattice (comparable to Raman).

  • Emission filters therefor should be 650LP.

Fluorescence Lifetime

  • Fluorescence Lifetime is approx. 12ns.

Measuring NV centers

Figure2: Jablonski diagram of the luminescent transition of the nitrogene-vacancy in a diamond lattice. Bright fluorescence corresponds to the ^3E→^3A (m_s=0) transition

Due to their photo-physical stability the NV-ceneters make for excellent demonstration samples for antibunching measurements. They are also potential candidates to image the confocal volume.

The following will explain how to find and measure NV-centers in bulk diamond.

System setup

  • refractive index of diamond is 2.4. that means oil immersion is necessary as well as a high N.A.
  • used objective: N.A. 1.3 is working, better 1.45 oil!
  • Although measurements were possible also with the water immersion objective: with 60×1.2 water less than 50% count rate in comparison to 100×1.3 oil
  • 0.95 N.A. air objective did not yield any usable results.
  • excitation source: 532 nm
    • MOFA (40MHz - for finding the centers, later 10MHz (12ns fluorescence lifetime))
  • excitation power: >7000 a.u. @ 40MHz, > 2000 a.u. @ 10MHz (basically as high as possible)
  • major dichroic: 532 / 635
  • emission bandpass: 690/70 (for antibunching measurements 2 bandpasses directly in front of detectors)
  • objective: 1.3 N.A. oil immersion
Figure3: fluorescence spectrum of a single NV center in diamond excited with 532 nm

Mounting the sample

sample is mounted directly on top of the objective (with immerision oil, without any coverslips etc.).

Imaging/ finding nv centers

  • focus on the interface between oil and diamond (nice reflection should be visible due to refractive index mismatch between oil and diamond)
    • when imaging the surface most likely fluorescent spots will be found. Those are probably dirt and unlike the NV-centers will bleach in a matter of seconds. They also have a shorter fluorescence lifetime.
Figure4: Prescan of NV-centers in bulk diamond. 5 micrometer into the sample, 80×80 micrometer, 150×150 pixel resolution. 532nm excitation, 690/70 emission, 40MHz rep. rate, approx. 7000 a.u.
  • move approx. 5 micrometer into the sample.
  • Although photo-physical stability makes the nv-centers ideal single emitter samples compared to single molecules the laser power to excite them has to be considerably higher. (0.1 mW and above).
  • Figure 4 shows a prescan of the complete field of view. The orange dots are NV-centers.
  • zoom into a region with a few NV-centers (see figure 5),
  • select one, and position the focus on the NV-center.
  • use the oscilloscope and pifoc+piezo to move the NV-center in x,y and z into the center of the focus.
  • For lifetime analysis switch laser repetition rate to 10MHz (see figure 6)
  • check whether the fluorescence lifetime is around 12 ns.
  • the NV-center's emission should stay stable (no bleaching)
Figure5: NV-centers in bulk diamond. 5 micrometer into the sample, 532nm excitation, 690/70 emission, 40MHz rep. rate, 6789.96a.u., 2ms/pixel, 15×15 micron

Typical Measurement Results

  • Prescan should look like figure 4
  • smaller area is depicted in figure 5 and figure 6
  • Selecting a ROI in figure 6 and plotting the fluorescence lifetime histogram should resemble figure 7
  • when measuring the fluorescence intensity of a single NV center, the count rate should stay stable. The time trace in figure 8 shows a reduction of the countrate due to stage drift (temperature etc, or in this case probably because the MT200 inhouse II was mounted on a wheelbarrow instead of an optical table)
  • to perform antibunching measurements on a selected NV-center choose a NV-center that is isolated, measuring time of 120 s should be enough to yield an antibunching measurement comparable to figure 9.

NOTE: Measurement setup has to be changed (see antibunching measurements)

Figure6: same as figure 5 but recorded with 10 MHz rep rate., 2304.94 a.u.;4 ms/pixel 45 min rec. time!
Figure7: Fluorescence Lifetime Fit of a selected NV center, 10 Mhz reprate, Inhouse II, MPD/SPAD
Figure8: No bleaching visible. reduction in count rate is due to mechanical drift (inhouse II) on wheelbarrow
Figure9: Antibunching measured on NV-center. Acquisition time 120 s, 1.3 N.A. oil immersion, 3534.98 a.u. 532 nm 690/70 emmission filters

References

M. Boersch, R. Reutera, G. Balasubramaniana, R. Erdmann, F. Jelezkoa, J. Wrachtrup Fluorescent nanodiamonds for FRET-based monitoring of a single biological nanomotor FoF1-ATP synthase Proc. of SPIE Vol. 7183, 71832N (2009)
http://dx.doi.org/10.1117/12.812720

howto/diamond_nv_centers.txt · Last modified: 2018/04/19 12:11 by admin