Abstract
Stimulated emission is the process fundamental to laser operation, thereby producing coherent photon output. Despite negatively charged nitrogen-vacancy (NVâ) centres being discussed as a potential laser medium since the 1980s, there have been no definitive observations of stimulated emission from ensembles of NVâ to date. Here we show both theoretical and experimental evidence for stimulated emission from NVâ using light in the phonon sidebands around 700ânm. Furthermore, we show the transition from stimulated emission to photoionization as the stimulating laser wavelength is reduced from 700 to 620ânm. While lasing at the zero-phonon line is suppressed by ionization, our results open the possibility of diamond lasers based on NVâ centres, tuneable over the phonon sideband. This broadens the applications of NVâ magnetometers from single centre nanoscale sensors to a new generation of ultra-precise ensemble laser sensors, which exploit the contrast and signal amplification of a lasing system.
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Introduction
The negatively charged nitrogen-vacancy centre in diamond1 has found wide applicability in quantum information2,3,4 and sensing5 of magnetic fields6,7,8,9,10,11, electric fields12,13, temperature14,15, pressure16 and biosensing17,18. For both readout and sensing, fluorescence that is, spontaneous emission is collected and the spin state is inferred from the different emission levels. The time-averaged spontaneous emission from the different spin states differs by no more than 30% and spontaneous emission is in all directions, creating the challenge of collecting the emission19.
Photons created by stimulated emission, on the other hand, have the same phase, wavelength and spatial mode as the stimulating light field. This enables close-to-unity collection efficiency as all photons are emitted into the same mode. Furthermore, the competition between spontaneous emission and stimulated emission potentially allows contrast of several orders of magnitude between the brightest and least bright state of the NVâ centre compared with the typical 30% for single centres and 4% for ensembles under spontaneous emission.
Stimulated emission is also the basis for lasing, but despite the success of diamond Raman lasers20 and despite an early proposal for a laser based on diamond defects21, and the demonstration of cavity coupling10,22 a realization of an NV laser has not been demonstrated so far. Microscopy, based on stimulated emission depletion, a super-resolution technique taking advantage of emission reduction by a strong light field, has been successfully implemented with NV centres23 as well as NVN centres24. However, the photophysical process leading to said emission reduction, be it stimulated emission to the ground state, or photo-ionization to the charge neutral NV0 state25,26,27 has not been extensively studied in this context. Indeed, photo-ionization of the NVââNV0 has been shown to be induced by strong light pulses28,29,30,31. The ionization process has been suggested to be a two-photon process26,28,29, which scales quadratically with laser power, for the wavelengths around the zero-phonon line (ZPL) of NV emission. Excited state absorption, for example via the ionization channel, can lead to weakening of stimulated emission by driving towards NV0. Insight into stimulated emission of NV centres is particularly important, since both ionization and stimulated emission by a strong light pulse result in reduced NVâ spontaneous emission and are therefore hard to distinguish, and also owing to the multitude of applications benefiting from these competing processes.
Here we show experimentally that light with wavelengths above 650ânm does not induce net ionization of NVâ centres, for powers up to a few Watts during the pulse, and show strong evidence for the presence of stimulated emission in the NVâ phonon side band. We use a green (532ânm) CW pump-laser together with a pulsed laser source with tunable wavelength to measure stimulated emission at different wavelengths. The pulses, with a duration of only 6âps, provide an intense light field and create a measurable change in the emission properties. Since the emitted photons are indistinguishable from the laser pulse, we initially detect the stimulated emission indirectly by the reduction of spontaneous emission. In subsequent measurements, we demonstrate enhanced emission at the wavelength of the stimulating laser as direct evidence for stimulated emission. In addition, we measure the excited state population of both charge states separately by monitoring the corresponding ZPL intensities to detect any potential ionization. Our results show the presence of stimulated emission and the possibility of lasing with NVâ centres.
Results
Stimulated emission and experimental setup
Conventionally, both sensing and quantum state readout in the NVâ centre is performed via fluorescence measurements after optical pumping, typically by exciting at a wavelength around 532ânm, from the 3A2 ground state, which we denote |1ã, to the 3E excited state |2ã, see Fig. 1a. Spontaneous emission occurs at a rate â(12âns)â1 over the characteristic NVâ spectrum with ZPL at 637ânm, corresponding to the |1ãâ|2ã transition, and with phonon-sideband emission from 637 to â¼800ânm, corresponding to transitions from |2ã to short-lived vibronic states slightly above |1ã with added phonons, followed by a rapid decay to |1ã (refs 32, 33).
(a) Nitrogen-vacancy centre (NVâ) level structure including phonon-added states (dashed and |3ã) with pumping and emission rates. Laser pumping (green) lifts population to the excited state, which can then decay via spontaneous emission (straight black arrows) or stimulated emission (red) due to interaction with a light field whose wavelength matches the |2ãâ|3ã transition. (b) Laser excitation (red and green columns) with short pass and notch (grey). This setup blocks laser light from the detector but still allows to monitor both NVâ and NV0 emission. Example spectra are included: NVâ emission (orange), NV0 emission (blue) and mixed emission (grey). (c) Experimental setup.
Stimulated emission due to a coherent light field of wavelength λ interacting with the NV centre occurs at a rate Îred=Ïλ I/(ħÏλ) where I is the power per area of the light field, ħÏλ the corresponding photon energy and Ïλ the stimulated emission cross-section, which as a function of λ is proportional to the NV emission spectrum, that is, the spontaneous emission rate. Strong stimulated emission is achieved by strong fields, produced for example, in optical cavities or in our case by a pulsed supercontinuum source.
The rate of stimulated emission is increased for laser light in the phonon-sidebandsâ wavelengths because the phonon-sideband emission is stronger than the ZPL emission, therefore the cross-section for decay on the phononic sidebands is higher. Accordingly, we choose a pulsed laser excitation around 700ânm (red light) at the peak of the phonon sideband, Fig. 1b, to achieve strong stimulated emission at the same wavelength. This laser is resonant with the transition between the excited state |2ã and a phonon-added ground state |3ã and induces a stimulated emission rate, which competes with the spontaneous emission, Fig. 1a. The red laser will therefore enhance the emission probability around 700ânm and reduce the emission probability for the rest of the NV spectrum. For lasing, population inversion is also easier to obtain on the sideband transition since the population in |3ã decays quickly and therefore it is no longer necessary to pump more than 50% of the NV centres out of the ground state |1ã. Our present setup, however, is not designed for self-sustained lasing because the light field does not build up in a cavity but is provided by the pulsed laser. The stimulated emission can therefore not be measured directly, since it is indistinguishable from the stronger pulsed laser signal. However the reduction in the rest of the NV emission spectrum can be detected. This reduction can be turned on and off with the red laser.
Obtaining full NV emission spectra is challenging when a strong laser at the centre of the NV emission spectrum (â¼700ânm) is used. We used a 650ânm short pass and a 532ânm notch in front of the detector to block out the pulsed red laser and the green (532ânm) CW pump laser respectively before the light was detected with a spectrometer or avalanche photodiode detector (APD), Fig. 1b. This detection window allowed us to monitor both the NVâ ZPL at 637ânm as well as the NV0 ZPL at 575ânm. Ionization is expected to increase the emission of one peak at the cost of the other and can be clearly distinguished in this setup from stimulated emission, which should decrease the emission in the entire monitored range of wavelengths. Even in the case that ionization NVââNV0 occurs both ways during the 6âps pulse, the emission spectrum, which is mainly obtained in the 12.5âns between pulses, should reflect the new relative charge state populations. The short pass optical filter allows us to vary the red laser wavelength, that is, measure stimulated emission as a function of wavelength.
We used a pulsed supercontinuum source (Fianium WL SC400-8) with a 6âps pulse duration at a repetition rate of up to 80âMHz with a tunable filter, Fig. 1c, which allowed us to select both the centre wavelength (700ânm initially) and bandwidth (40ânm initially). The resulting time-averaged power of several mW corresponds to several Watts, during the pulse duration. The pulsed light was aligned via a dichroic mirror with the green CW laser and focused through an objective (NA=0.9) onto the NV diamond samples. We confirmed the effects on two â¼500âμm thick single-crystal diamonds as well as a nanodiamond sample, all with very high NV density.
Emission reduction of both ZPLs
To investigate the effect of the pulsed laser on the spontanteous emission, we first measured the NV emission between 550 and 650ânm when only the green CW laser excites the sample. We then measured the spectra when both the green CW and the pulsed laser at 700 with 40ânm bandwidth are on. The data in Fig. 2a was taken over 100âms acquisition time, which corresponds to 8 million pulses. The spectra are integrated over the entire acquisition time including the pulsed laser being on and off, and the spectra were smoothed with a running average over a 4ânm window. Figure 2a shows the emission with both the NV0 ZPL at 575ânm and NVâ ZPL at 637ânm clearly visible as expected since 532ânm pumping is known to excite both charge states of the NV. More importantly, the addition of the red pulsed laser reduces the entire emission in the observed wavelengths as expected when stimulated emission at 700ânm is induced. We note that the reduction occurs despite the fact that the red pulsed laser by itself creates weak excitation of the NVâ as discussed later. Both ZPLs (NVâ and NV0) are reduced, which indicates that the reduction of NVâ emission is not caused by ionization towards NV0. If ionization to NV0 occurred, then we would expect the increased NV0 population to provide an increase of the NV0 ZPL emission. Quite contrary, in Fig. 2a the NV0 ZPL is also reduced indicating that the NV0 population also experiences stimulated emission at 700ânm. While this might seem surprising, the phonon sideband of the NV0 extends over a slightly wider range than the NVâ and is quite strong at 700ânm, see Fig. 1b.
(a) Spectral emission of the NV centre ensemble due to 532ânm continuous wave (CW) laser excitation alone (green), and due to an added pulsed 700ânm laser excitation (blue). The emission with both lasers on is reduced compared with only green CW excitation. This is consistent with a preferential emission at 700ânm due to stimulated emission. (b) When the pulsed laser wavelength is changed to also be at 532ânm, the emission is increased by the pulsed laser. All the spectra were smoothed with a 4ânm window. (c) Two regimes exist: the NV0 emission is decreased by the addition of pulsed laser wavelengths above 680ânm, where stimulated emission dominates, and increased for pulsed wavelengths below 640ânm, where ionization from NVâ to NV0 is known to be the dominant process. In the measured range of wavelengths the pulsed laser alone does not create any NV0 signal, that is, there is no direct excitation. The pulsed power was kept constant at 2.9âmW for all excitation wavelengths.
Our interpretation attributes the emission reduction in the observed wavelength range to stimulated emission at 700ânm. As an initial check of this interpretation, we changed the pulsed laser wavelength to also be 532ânm, as the CW source. This is outside the NV emission spectrum and stimulated emission should therefore not occur. Figure 2b shows that in this case indeed the addition of the pulsed laser increases the total emission, proving that the effect of emission reduction by the added pulsed laser only occurs at certain wavelengths. For stimulated emission, this range of wavelengths would be expected to be the range of spontaneous emission, which we confirm further below.
How can the apparent occurrence of stimulated emission be brought into agreement with the established fact25,26,27,28,29,30,31 that strong light pulses around 637ânm efficiently decharge the NVâ to the NV0? To explore the photoionization, we reduced the pulsed laser wavelength, swapping the 650ânm short pass for a 600ânm short pass and monitored the NV0 ZPL. Again, we combined a green CW laser, which creates NV0 emission, with the pulsed red light, which by itself does not create NV0 emission. Any change in the NV0 signal after adding pulsed light must therefore be due to either stimulated emission or ionization. Figure 2c shows clearly the transition between two regimes: For pulsed light at high wavelengths, λ>680ânm, the NV0 signal is reduced as discussed above and stimulated emission dominates. For pulsed light at lower wavelengths, λ<640ânm, the NV0 signal is increased and ionization from NVâ towards the NV0 is the dominant process25. The threshold between the two behaviours seems to be around 660ânm, that is, a photon energy of 1.88âeV. This energy value is slightly higher than theoretical calculations of the minimal energy value required for ionization from the NVâ excited state, which were predicted as 1.56 eV in ref. 29 and 1.7 eV (private communication with Audrius Alkauskas). Note that this value is not to be confused with the ionization energy from the NVâ ground state of 2.6âeV (ref. 28).
The relative emission reduction at the NVâ ZPL in Fig. 2a is about 18% and about 21% in the measurement of Fig. 2c for 700ânm pulsed wavelength. Assuming that the red intensity in the region of focus is intense enough to fully deplete the excited state via stimulated emission, this means that 18 to 21% of the NV centres that contribute to the signal are in the region of focus. Since we used a 500âμm thick sample, the percentage value of focus volume relative to illuminated volume seems high but is realistic given that there is non-uniform intensity in all dimensions of the laser spot and considering that NV centres in the focus volume contribute more strongly to the emission signal.
Emission dynamics
While stimulated emission should only occur during the 6âps pulse duration, a reduction by other indirect effects could show other timescales or no temporal structure. Changes in the emission due to ionization have been found to occur typically on much slower timescales of microseconds to milliseconds25,26,30.
We therefore measured the total emission (not spectrally resolved) in the detected emission window (550ânm to 650ânm, see Fig. 1b) with an APD and time-correlated counting card with a 0.1âns temporal resolution. While the 6âps pulse is not resolved on that scale, the dynamics between pulses is resolved. The time between pulses was set to 25âns, corresponding to a repetition rate of 40âMHz. Figure 3a shows that the reduction due to the added pulsed laser (blue curve) relative to the green CW laser (green curve) occurs faster than the time resolution of the electronics and then the signal recovers between pulses due to the green CW pump, as expected. The emission due to the pulsed laser only (red curve) shows that the 700ânm pulse alone actually weakly excites the NVâ centre. The time point of this excitation coincides with the reduction of the emission of the blue curve, that is, the time point of the pulse.
(a): raw data of temporally resolved emission which is spectrally integrated below 650ânm. The fluorescence reduction occurs instantly at the point in time of the red pulse. Then the emission recovers in between pulses. (b) Temporal emission curves for different pulsed excitation wavelengths (c) The minimal relative emission directly after the pulse as a function of the pulsed excitation wavelength shows that the greatest reduction in emission occurs around 700ânm corresponding to the peak of the phonon sideband of the NV. The error bars give the standard deviation of the temporal data points averaged for each value.
To further investigate the wavelength dependence, discovered in Fig. 2, we varied the centre wavelength of the pulsed laser in 20ânm steps. The full width at half maximum of the laser was also set to 20ânm to ensure no overlap between the steps. The strength of the reduction varies with the wavelength of the pulsed laser (Fig. 3b,c) and shows that the effect is the strongest at 700ânm and reduces towards 800ânm. To ensure the data are independent of the small power variations of the source, which occurred when changing wavelengths, we measured the power for each wavelength and rescaled the reduction accordingly. Figure 3c shows the relative emission level right after the pulse (averaged over 10 data points). As expected for stimulated emission, the effect occurs for wavelengths within the NV emission spectrum and is strongest around 700ânm, which corresponds to the peak of the phonon sideband.
To understand the temporal dynamics, we modelled the NV by a simple three-state system (Fig. 1a). This model neglects the spin dynamics but is a good approximation since the green CW laser spin-polarizes into the ms=0 state and all emission processes are spin-conserving. The differential equations for the system probabilities Pj to be in the states |jã in Fig. 1a are:
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where the pulsed laser created a stimulated emission rate Îred(t) with a temporal Gaussian profile with standard deviation 6âps, repetition rate of (25âns)â1=40âMHz and overall strength is fitted to match the experiment. When we give time-independent values for Îred below, we give the equivalent rate that a 6âps square pulse would have. The spontaneous emission rate to |3ã was taken to be L23=18âMHz from ref. 34. All spontaneous emission rates to states other than |3ã were grouped into one rate of L21=65.3âMHz directly from state |2ã to state |1ã. The value was chosen to correspond to a total lifetime of 12âns for the excited state. The phonon-decay rate was set to L31=1âTHz but the exact value is irrelevant provided it is fast compared to all other transition rates. Starting the system in state |1ã with the constant pumping rate Îgreen we time-evolved the system via numerical integration until it reached a steady state; we then included the time-dependent repeating red pulses in the evolution.
In the simulations without the red pulses, the steady state has a given population in the excited state. Including the red pulses leads to stimulated emission on the |2ã to |3ã transition over the 6âps pulse duration. This depletes population from the excited state to |3ã, which then decays to |1ã due to the fast phononic decay. In the 25âns between the pulses, the population of the excited state slowly recovers to its original value due to the constant green pumping rate. The number of spontaneously emitted photons also drops during the pulse duration and then recovers in between pulses because it is proportional to the excited state population. The timescale of the recovery is roughly the time between pulses, that is, 25âns, and decreases (that is, the recovery rate increases) with increasing green CW pump power.
To quantify the expected wavelength dependence for the effect for stimulated emission, we modelled different wavelengths of the pulsed laser by varying the stimulated emission cross section proportional to the measured NV emission spectrum with a maximum of Îred=6âGHz at 682ânm. The pump rate was set to Îgreen=92âMHz and Fig. 3c shows that the resulting theoretical wavelength dependence of the relative emission matches qualitatively with the experimental measurements. We note that a transition rate of order GHz is realistic for a pulsed source with powers of few W during the 6âps pulse, and a focus-area on the order 1âμm2.
The wavelength dependence is further evidence for stimulated emission as opposed to ionization. Ionization of the NV centre has been explained as an absorption process from the excited state to the conduction band. The absorption to the conduction band should therefore not show any wavelength dependence since the band can accommodate different photon energies. There should only be a sharp drop of the effect once the photon energy becomes too small (that is, wavelength too long) to reach the conduction band. Ionization should furthermore be more likely with increased excited state population, that is, increased absorption. If the emission reduction was caused by ionization then the wavelength dependence would follow the absorption spectrum of the NV, which has its phonon sideband and maximum in wavelength range around 550ânm (below the ZPL) and not around 700ânm (above the ZPL)25.
While the pulsed laser wavelength changes the strength of the emission reduction, it does not seem to change the timescale of the recovery in Fig. 3b. This behaviour matches our simulations. The recovery of the emission in between pulses is approximately exponential. In the case that the effect is caused by stimulated emission the recovery should be purely caused by the green CW pump. For other effects, such as ionization, the recovery could be either explained with the crystal returning to its equilibrium state, with a rate set by internal NV or crystal parameters, which should be slower and independent of the green pump rate. For ionization, the recovery could also be explained by the green laser ionizing back to the NVâ state, which has previously been measured to occur at a rate of (0.25âμs)â1 for a 532ânm laser at 0.25âmW power (see Fig. 3c in ref. 26), which is an order of magnitude slower than the rate we find.
Figure 4a shows a measurement of the emission dynamics with varying powers of the green CW pump power. The pulse repetition rate was reduced to (100âns)â1=10âMHz to ensure that the system has enough time to return to its equilibrium state between pulses. Since stronger green CW pumping leads to higher total emission, we plot the relative emission as a percentage of the highest total emission respectively. We observed a shorter recovery time, i.e., faster recovery rate, for stronger green CW power: in Fig. 4a, the lowest power (pink curve) has the slowest recovery rate. With increasing green power (light blue, orange, dark blue), the emission recovers faster and the highest power (green) shows the fastest recovery rate. The recovery time for 0.25âmW (pink) is â¼25âns, which is much faster than the expected 250âns for ionization26. The recovery timescales are consistent with stimulated emission as demonstrated below. For lower green powers, the relative emission reduces to only â¼97% (pink) rather than â¼93% (green and dark blue). This is explained by the fact that the red pulsed laser weakly excites the NV as demonstrated below.
The observed dynamics was reproduced by our simulations: corresponding curves are plotted in the same colours in Fig. 4a,b. The stimulated emission rate was set to Îred=13âGHz to reproduce the relative emission reduction to â¼93% for large powers. The pump rates were varied proportional to the green laser powers in the experiment from 8.8 to 141âMHz, which corresponds to an average focus area of (0.6âμm)2, given the known absorption cross-section 0.95 à 10â16âcm2 (ref. 35). These pump rates lead to recovery timescales similar to the experiment both in absolute values and relative trend between the curves. To reproduce the fact that lower green powers show a weaker emission reduction effect, we included an excitation rate of Îred2=0.85âGHz due to the red pulse from ground to excited state:
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This rate Îred2 was calculated using the weak effective absorption cross-section for NVâ at 700ânm, which we measured to be 3 Ã 10â2âm24. We had initially neglected this as it is only a weak effect but we found that for low green powers (which resulted in weak total emission) the inclusion of this effect in the modelling was a good explanation for why the pink curve only reduces to â¼97% while higher green powers reduce to â¼93%.
All measurements so far were taken with single crystal diamond. We compared a single crystal sample to nanodiamonds on a silicon substrate under the same conditions. The same effects were observed and confirmed the generality of our results, see Supplementary Note 1.
Direct measurement of stimulated emission
As final confirmation that the emission reduction is caused by stimulated emission we have measured the stimulated emission at the stimulating wavelength directly. To measure the stimulated emission signal against the much stronger red laser signal and its associated noise, we have modulated the green pump laser with a frequency of 548âHz and changed the red laser from a pulsed to a CW source. For details of the setup, see Fig. 5a and the âMethodsâ section. Thus, a stimulated emission signal due to the green pump laser must also be modulated, while the red laser signal is not. A lock-in amplifier allowed us to filter only the frequency of interest and thus removed the red laser signal and a majority of the noise. Figure 5b shows that the resulting signal is indeed almost zero when only the red CW laser is on. When only the modulated green pump is on some spontaneous emission is produced at the modulation frequency but we block most of that out with a 705ânm bandpass filter to see only stimulated emission. When the red CW laser is added to the green pump laser, Fig. 5 shows that the emission signal increases linearly with the red stimulating laser power. This increase is only measured because it oscillates at the modulation frequency of the green pump and is thus clearly stimulated emission because it is pumped with the green laser and emitted due to the red laser. This is the first direct measurement of stimulated emission from the NV centre. We note that the spontaneous emission signal from only the green laser is negligible compared with the stimulated emission signal for two reasons: We used a bandpass filter around the red laser wavelength and thus removed the majority of spontaneous emission and additionally the spontaneous emission is isotropic and only the fraction of the solid angle of the collecting objective is detected whereas the stimulated emission is directional in the stimulating beam direction and therefore has very high collection efficiency. This leads to the given configuration with excellent contrast between the stimulated emission signal and the spontaneous emission from the green laser. For higher green powers, the spontaneous emission signal strengthens while the detection contrast is not as strong. This measurement was performed in transmission through the sample using an objective on each side, see Fig. 5a.
(a) Setup with modulation on the green laser and a lock-in amplifier filtering the detection signal for only the modulation frequency (b) The red CW laser creates stimulated emission. Because the stimulated emission is dependent on the green pump laser, it also oscillates at the modulation frequency and is hence detected. The red CW laser signal itself is unmodulated and is thus filtered out by the lock-in amplifier. The green laser by itself creates fluorescence, which is almost entirely filtered out by the 705ânm bandpass and additionally only the fraction that is emitted into the solid angle of the objective is directed to the detector. The stimulated emission is emitted into the laser beam direction and is thus entirely collected by the detector and gives a clear signal linear with stimulating power. The blue and red dashed lines are linear fits.
Discussion
We have shown clear signatures of stimulated emission in NV centres in single crystal diamond as well as nanodiamonds. We demonstrated the spontaneous NV emission from a green CW pump laser and the reduction of this spontaneous emission due to a strong pulsed red laser at the centre of the phonon sideband (â¼700ânm). We explain this reduction in spontaneous emission as being due to stimulated emission at 700ânm. The measured emission reduction follows all the expected behaviour for stimulated emission in terms of its dependence on the wavelength of the pulsed laser, the spectral reduction of both the NVâ and the NV0 ZPL, as well as the temporal dynamics, including emission reduction during the laser pulse and a recovery rate that varies with the green laser power. Our theoretical modelling of stimulated emission also reproduces the measured effects.
Particularly we show that for wavelengths â¼700ânm stimulated emission is the dominant process over ionization. This is indicated by no increase of either ZPL line, a wavelength dependence, which follows the emission rather than the absorption spectrum and a temporal dynamics inconsistent with ionization. We furthermore showed the transition to the regime where ionization dominates, which is when the pulsed laser is set to wavelengths around the NVâ ZPL. Our results are therefore consistent with previously reported photoionization studies NVââNV0 induced by wavelengths below 650ânm.
Our findings manifest that stimulated emission dominating over ionization is dependent on the wavelength (rather than the intensity), which should be in the phonon sideband λ>650ânm. This is in agreement with previous literature on super-resolution microscopy, where stimulated emission depletion was achieved with wavelengths λ>700ânm pulses36,37,38, whereas charge state depletion was achieved with 637ânm pulses39,40.
The measurement of the effect in both single-crystal diamond and nanodiamonds shows sample-independent applicability.
Our results show that stimulated emission can be utilized in the NV and lead the way to exploring the benefits of stimulated emission, for example, for higher collection efficiency into a cavity mode. Our results also indicate that NV centres are suitable as a laser medium. This opens up new avenues of applications for the NV centre.
We estimate the conditions for lasing with NV centres for the three-phonon sideband transition at 709ânm, where stimulated emission strongly dominates. Lasing is possible, when the rate of stimulated emission into an optical cavity is greater than the loss rate κ of the cavity. The stimulated emission rate can be calculated41,42 on the basis of the cavity and spontaneous emission characteristics. From this condition, we find the minimum density of NV centres to achieve lasing:
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where c is the speed of light, n=2.4 the refractive index of diamond, λ=709ânm the free-space wavelength of the three-phonon sideband, ν23=c/λ the corresponding frequency, Îν23â24âTHz the corresponding width of the three-phonon peak15,43, lcav the cavity length, the cavity finesse, Vcav the cavity mode volume and Vdiam the diamond volume within the cavity mode. From this equation, we see that the required density reduces proportional to 1/finesse and that lasing is in principle possible with a commonly achieved density of 0.1 to 1âp.p.m. even for low-finesse cavities. However, low-finesse cavities will require very large pump powers for lasing. The required power at the lasing threshold can be estimated by the absorption cross-section and enforcing the detailed balance condition for the excited and ground state population Ïexc/Ïgr=Î/Î with pumping rate Î and emission rate Î at threshold, which is valid for not too small NV numbers in the cavity. We obtain
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This shows that while lasing is challenging, it should be possible, for example, for a cavity of 1âmm length with finesse =105 and average illumination area Acav=1âmm2 and an illuminated diamond volume that is half the cavity volume with an NV concentration [NV]=1âp.p.m. requiring a pump power of 240âmW. We confirmed numerically that this analytical approximation gives a good estimate for the required power by solving numerically the full seven-state model1 of the NV centre coupled to a laser cavity42.
Laser threshold magnetometry42 was recently proposed as a novel way of measuring magnetic fields with NV centre ensembles, enabling higher contrast and stronger output signals using stimulated emission. By driving an NV laser at the threshold, sensitivities down to fT Hzâ1/2 could be achieved and could enable a robust, room-temperature alternative for SQUID sensors. The current results support the feasibility of the laser threshold sensing scheme.
Methods
Diamond sample preparation
We confirmed the effects on different diamond samples: sample A was a single crystal, type 1b, irradiated with 2âMeV electrons to 2 à 1018âeâcmâ2, annealed at 800â°C for 5âh. Sample B was a single crystal, type 1b, irradiated with 2âMeV electrons to a fluence of 1.1 à 1018âeâcmâ2 and annealed in vacuum at 900â°C for 2âh. During irradiation, the sample was in a dry nitrogen environment and kept at temperature below 800â°C to avoid any surface degradation. Sample C was a single crystal, type 1b, irradiated with 2âMeV electrons to a fluence of 1 à 1018âeâcmâ2 and annealed in vacuum at 800â°C for 2âh. Sample C was 50âμm thin used specifically for Fig. 5 to fit between the two objectives. Sample D were nanodiamonds, see Supplementary Note 1,irradiated with 2âMeV electrons to a fluence of 1 à 1018âeâcmâ2, vacuum annealed at 800â°C for 2âh, then oxydized in air at 510â°C for 4âh.
Lasing conditions calculations
To obtain an analytical estimate for the required pump power Pthresh, connected to the pump rate Îthresh=PthreshÏ/(AcavħÏ) via the known absorption cross-section Ï and the photon energy ħÏ, we enforced the detailed balance, that is, the ratio of transition rates equal the ratio of populations for the ground and excited state Ïexc/Ïgr=Î/Î from which we obtain the excited state population Ïexc=Î/(Î+Î)âÎ/Î for a high enough number of NV centres such that at threshold, which we confirmed numerically for
. Combining the detailed balance condition with the lasing condition GÏexc=κ for the coupling G of NV centres and cavity and cavity loss rate κ, we find the required pump rate for lasing Îthresh=Îκ/G from which we can then calculate the required power Pthresh. We note that the expression becomes invalid when the absorbed power under homogeneous illumination Pabs=nNVnCVcavÎħÏ>Pthresh, since the laser medium becomes strongly absorbing in this case. Here nC is the carbon density of diamond. This can be easily monitored and happens for very long cavity designs and very high NV densities.
Setup for direct measurement of stimulated emission
For the direct measurement of stimulated emission, we modulated the green 532ânm laser with an optical chopper at a frequency of 548âHz and combined this via a fibre beam splitter with a CW 705ânm red laser. Since the stimulated emission is directional in the stimulating beam direction, we measured in transition using one objective ( à 10, NA=0.25) to focus the beam inside the sample and one objective ( à 40 NA=0.65) to collect the light after passing the sample once. Owing to the short working distance of the lenses, we used a thin sample of only 50âμm thickness to ensure the ability to focus both objectives to the same point in the sample and collimate the outgoing beam. The signal was detected via a variable gain detector and then frequency filtered with a lock-in amplifier using the chopper frequency as a reference. Thus we ensured that only emission caused by the green pump laser was detected. Since the spontaneous emission is isotropic only the fraction that goes into the solid angle of the collecting lens is detected. The directional stimulated emission is collected entirely when the outcoming laser beam is collimated by the collecting objective.
Data availability
The data that support the findings of this study are available from the corresponding author on request.
Additional information
How to cite this article: Jeske, J. et al. Stimulated emission from nitrogen-vacancy centres in diamond. Nat. Commun. 8, 14000 doi: 10.1038/ncomms14000 (2017).
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Acknowledgements
We thank Jason Twamley, Neil Manson and Audrius Alkauskas for useful discussions and comments. This work was supported by the Australian Research Council under the Discovery (ARC DP130104381), LIEF (LE140100131), Centres of Excellence (CE110001013 and CE140100003) and Future Fellowship (FT110100225) schemes.
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JJ, DWML, LPM, PR, JHC, BCG, ADG, XV and TV conceived and planned the experiments. JJ, DWML, XV, LPM and PR carried out the experiments. JJ, ADG and JHC planned and carried out the simulations. SO, TO, JJ, DWML, PR, LPM, FJ, BCJ and JCM contributed to sample preparation. JJ, DWML, XV, LPM, PR, MWD, FJ, TV, JHC, BCG and ADG contributed to the interpretation of the results. JJ took the lead in writing the manuscript. All authors provided critical feedback and helped shape the research, analysis and manuscript.
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Jeske, J., Lau, D., Vidal, X. et al. Stimulated emission from nitrogen-vacancy centres in diamond. Nat Commun 8, 14000 (2017). https://doi.org/10.1038/ncomms14000
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DOI: https://doi.org/10.1038/ncomms14000
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