Expand this Topic clickable element to expand a topic
Skip to content
Optica Publishing Group

Xenon implantation of nanodiamond films for targeted color center emission at sub-nanosecond time scales

Open Access Open Access

Abstract

In this work, the lifetime of nitrogen-vacancy color centers within nanodiamonds is reduced from 550±13 ps to 297±10 ps through the implantation of xenon. Coupled-mode analysis is employed to characterize the mechanism responsible for the reduction in emission lifetime. The observed spectral lineshape is found to be consistent with a Voigt profile consisting of two Lorentzian resonant peaks at 637 nm and 811 nm that are inhomogeneously broadened by a Gaussian distribution. A convolution of the frequency-domain Lorentzian output, with linewidths less than 1 nm, from the coupled-mode system of equations with a Gaussian with standard deviation of 85 nm is performed to generate the Voigt profile. The shortened emission lifetime is found to be consistent with a coupled mode theory model incorporating coupling between nitrogen-vacancy and xenon-vacancy color centers.

© 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

1. Introduction

Quantum information technology is a rapidly growing field that calls for technologies that prepare, evolve, and measure quantum bits (qubits) to be successful [1]. Evolution technologies that allow qubits to be transferred and interact optically are likely to include solid-state optical quantum emitters [2]. Quantum emitters, comprising a host of technologies such as quantum dots, rare earth impurities, and color centers in diamond have many applications. They can produce indistinguishable single photons on demand [37], enable interactions between single photons [8], and can store and process quantum information in the spin states [911]. Quantum emitters can also sense electromagnetic fields [12,13] at nanoscale dimensions. The color centers in nanodiamond are an example of a set of quantum emitters that have been studied extensively [14].

Many varieties of nanodiamond color centers have been evaluated, such as iron, titanium, and xenon [14]. Each one exhibits different optical properties. The nitrogen-vacancy (NV) color center is the most commonly studied color center with over 50 years of research [15].

The NV center is a point defect in diamond with ${C_{3v}}$ symmetry consisting of a substitutional nitrogen-lattice vacancy pair oriented along the [111] crystalline direction. It is created in the chemical vapor deposition of diamond, or by radiation damage and annealing, or by ion implantation and annealing in bulk and nanocrystalline diamond. The NV center is known to have negative ($N{V^ - }$) and neutral ($N{V^0}$) charge states. These charge states are identified by their optical zero phonon lines (ZPLs) at 1.945 eV (637 nm) and 2.156 eV (575 nm) respectively [16]. The associated vibrionic bands extend from their ZPLs to higher/lower energy in absorption/emission.

Both charge states of the NV color center have been identified as room temperature single photon sources [1719]. This was confirmed through statistically-significant antibunching dips observed through second-order autocorrelation measurements [often abbreviated as ${g^{(2 )}}(\tau )$].

While NV color centers offer the attractive feature of room temperature single-photon emission, one of the key obstacles to the utilization of nitrogen vacancy color centers in quantum information technologies are their long bulk emission lifetimes, typically 80 ns [20]. These lifetimes do not support the fast repetition rates necessary for most quantum information applications [21].

Attempts have been made to shorten the emission lifetimes of NVs using various methods, such as coupling to surface plasmons [20], modifying the substrate refractive index [22], or introducing radiation induced lattice defects (RILDS) [23]. These methods have been largely successful, but come with various tradeoffs, such as decreased emitter intensity when applying RILDs, or difficult and irregular construction when plasmonic methods are utilized.

In this work, we describe a precise fabrication method for the shortening of NV color center lifetimes while preserving their broadband emission and intensity.

We discuss first the fabrication and initial optical characterization of nanodiamond films and their subsequent ion implantation with xenon. The post-implant optical characterization is discussed before concluding with an analysis of our findings using coupled mode theory. In our analysis, we create a model of our system using idealized components, and the associated coupled-mode system of equations. Next, we solve the system of equations to obtain analytical expressions for the spectral intensity lifetime before generating a Voigt profile, representing our model’s frequency response, that is in good agreement with the experimentally observed lineshape of our color centers.

2. Methods

We conducted the nanodiamond film assembly process in two stages: film deposition and ion implantation. In the first stage, we created a very dense film to increase the chances of successful ion implantation using the Salt-Assisted Ultrasonic disaggregation (SAUD) [2228]. In the second stage, ion implantation of xenon was performed at Sandia National Laboratories.

All optical characterization was performed using a custom-made scanning confocal microscope. Further details of all these procedures are included in the Supplement 1 provided.

3. Results and analysis

3.1 Film characterization

Dynamic Light Scattering (DLS) measurements were conducted with the Malvern Zetasizer ZS Nano. Post-SAUD, DLS measurements indicated that the z-average (intensity-weighted mean hydrodynamic size of the particles) decreased from 43 nm to 18 nm, with a polydispersity index decrease from 0.203 to 0.100. After analysis of the surface with a scanning electron microscope, the film was deemed to have good surface coverage.

Photoluminescence spectroscopy was subsequently performed using the fluorescence intensity measurement method on the film with a custom scanning confocal microscopy setup. PL measurements revealed the presence of several nitrogen vacancy color centers. Those color centers were analyzed, and a spectrum matching with that of a typical nitrogen-vacancy (NV) color center was observed from all regions of the film investigated.

3.2 Optical characterization

The film was implanted with xenon ions at Sandia National Laboratories, and subsequently annealed at 500°C for one hour. After implantation, the film was optically characterized using the same custom scanning confocal microscopy setup and was found to still contain several color centers. The spectrum shows a peak at ∼624 nm. This peak is red-shifted by 30 nm with respect to previous experiments involving xenon implantation into diamond. Previous experiments involving photoluminescence spectroscopy performed on nanodiamond agglomerates [24], as well as previous work detailing the size dependence of fluorescent nanodiamond emission [25]. The photoluminescence spectrum from the NV centers can vary depending on the particle size and agglomeration pattern [25]. For certain aggregation patterns, photoluminescence peaks around 630–650 nm can be observed in experiment [24], which is in the same spectral region that was observed in our sample. Previous experiments have shown that the emission spectrum of nitrogen vacancy color centers will vary according to excitation wavelength [2628] Our excitation wavelength was 532 nm, while the previous xenon-related work was excited at 514.5 nm. In this previous work, a characteristic $N{V^0}$ zero phonon line (575nm) was reported for samples annealed at 700${\circ}{C}$, showing good evidence of the contribution of NV-related emission in samples annealed at these temperatures. Our measured spectrum is also very similar to previous experiments involving the implantation of xenon into type 1A diamond [28]. Combining these papers supports our understanding that the measured spectrum reflects fluorescence from nitrogen-vacancy color centers.

Several scans were conducted, and no photobleaching was observed. Fluorescence lifetime measurements of color centers within the film were conducted at random within the field of view, which was made possible by the abundance of individual color centers. The measured lifetimes of color centers within the film were remarkably short (below 1 nanosecond), and displayed low variance across the sample, as expected, given the fluence rates of the implantation.

In our experiment, the measured fluorescence lifetimes of the color centers within the film typically exhibit a bi-exponential relationship, with two exponential lifetimes ${\tau _1}$ and ${\tau _2}$. The longer lifetime, ${\tau _2}$, is typically associated with color centers within the bulk of the nanodiamond, while the shorter lifetime ${\tau _1}$ is associated with surface effects [20,23].

Results from time-resolved photoluminescence are provided in Fig. 2. We performed a bi-exponential nonlinear least-squares fit on the experimental data to extract the relevant lifetimes and amplitudes, and then calculated the standard error of the lifetimes. The fluorescence lifetime of implanted color centers within the bulk were found to be ${\tau _2} = 297 \pm 10\; \textrm{ps}$, with the surface effect lifetime ${\tau _1} = 42 \pm 14\; \textrm{ps}$. This is a remarkable reduction in lifetime for nitrogen vacancies in nanodiamond, which typically have a fluorescence lifetime on the order of 40–80 ns [23]. A comparison to pre-implantation lifetimes yielded a similar bi-exponential relationship with the surface-associated lifetime ${\tau _1} = 38 \pm 8\; \textrm{ps}$ and the bulk lifetime ${\tau _2} = 550 \pm 13\; \textrm{ps}$. The pre-implant bulk lifetime observed can be attributed to the presence of C-Centers (single nitrogen substitution within the lattice), as has been reported in the literature [23], since the pre-Implant diamonds were type 1A diamonds that are known to contain several C-Centers [23]. The intensity of the post-implant fluorescence compared with the pre-implant fluorescence was also measured, and the post-implant fluorescence intensity was approximately twice that of the pre-implant fluorescence intensity. The two fluorescence measurements are documented in Fig. 1. The observed sharp decay from the pre-implant species is due to the higher contribution of surface effects ($\tau = 38 \pm 8\; \textrm{ps}$) in the observed fluorescence.

 figure: Fig. 1.

Fig. 1. Process flow diagram for Xe color center fabrication. a.) A nanodiamond film is deposited using disaggregated nanodiamonds in solution via electrophoretic deposition prior to ion implantation. b.) The resultant film is characterized via scanning electron microscopy and reveals good surface coverage. c.) The resulting film is implanted with Xe species at a fluence of ${\mathbf{10^{14}}}$ ${\textbf {ions}}/{\textbf c}{{\textbf m}^2}$; the resulting color centers are characterized via scanning photoluminescent (PL) spectroscopy (this image has a field of view of 20 × 20 µm2).

Download Full Size | PPT Slide | PDF

 figure: Fig. 2.

Fig. 2. Lifetime measurements are conducted on pre-implant (gray) and post-implant (blue) color center species. Pre-Implant and post-implant data is represented by the grey and black circles, respectively. Post-Implant color centers show a bulk lifetime of ${{\boldsymbol \tau }_\mathbf 2} = $297${\pm} {\mathbf{10}}$ ps. This is a 43% reduction in bulk lifetime compared to pre-implant color centers. The sharp decline in the pre-implant data is due to the higher contribution of surface effects (${{\boldsymbol \tau }_1} = $ 38${\pm} {\mathbf 8}$ ps) in the observed fluorescence.

Download Full Size | PPT Slide | PDF

Several attempts were made to explain the peculiar fluorescence characteristics of the post-implant film, such as the introduction of additional point C-Centers or other radiation-induced lattice defects. The results, specifically the increase in fluorescence intensity, the relatively unchanged surface lifetime, and shortening of only the bulk lifetime, are contrary to the predictions of prior work. The literature predicts a shortening of both bulk and surface lifetimes, as well as the lowering of the fluorescence intensity of nitrogen vacancy color centers as the number of C-Centers and other lattice defects grows [21]. This quenching effect is from the creation of non-radiative energy transitions within the ground and excited states of the nitrogen vacancy color centers. As these effects are not present here, it is fair to assume a different mechanism is responsible for the decreased lifetime, and increased fluorescence of the color centers. Coupled-mode theory calculations can be employed to help elucidate this mechanism in detail.

4. Discussion

Coupled mode theory was developed in the 1950s to analyze and design of a broad range of devices including microwave traveling-wave tubes, parametric amplifiers, oscillators, and frequency converters. Central to the theory is the analysis of lossless resonances, and their coupling to similarly lossless waveguides, and one-another. The theory serves as an approximate, yet insightful and accurate mathematical description of the electromagnetic oscillations and wave propagation for coupled systems [2931].

For the purposes of our analysis, we considered only the lifetime reduction associated with the nitrogen-vacancy color center in the bulk. The system was described as a two-resonator system with the field amplitudes of the lowest-order resonator modes in each resonator given by ${A_1}$ and ${A_2}$, corresponding to resonator 1 and 2 respectively. Each resonator possesses a resonant frequency denoted by ${\omega _{1,2}}$. A coupling term representing the weak coupling between the resonators was denoted by ${\tau _{12}}$. In our analysis, resonator 1 represents our pre-implant nitrogen-vacancy color center while resonator 2 represents a typical $Xe$ color center and we consider asymmetric and symmetric coupling between the two resonances. This two-resonator system is symmetrically coupled to two identical waveguides representing the propagation of EM waves in air on one side, and into the substrate on the other. These waveguides are known as waveguides 1 and 2, respectively. The coupling constants of resonance 1 to waveguides 1 and 2 are given by ${\tau _{11W}}$, and $\; {\tau _{12W}}$. The coupling constants of resonance 2 to waveguides 1 and 2 are given by ${\tau _{21}}$ and ${\tau _{22w}}$. All coupling constants are known via experiment or the literature. The resonances and coupling constants give rise to two simultaneous differential equations for symmetric coupling:

$$\frac{{d{A_1}}}{{dt}} ={-} i{\omega _{01}}{A_1} - \frac{1}{{{\tau _{11w}}}}{A_1} - \frac{1}{{{\tau _{12w}}}}{A_1} - \frac{1}{{{\tau _{12}}}}{A_1} + \frac{1}{{{\tau _{12}}}}{A_2}$$
$$\frac{{d{A_2}}}{{dt}} ={-} i{\omega _{02}}{A_2} - \frac{1}{{{\tau _{21w}}}}{A_2} - \frac{1}{{{\tau _{22w}}}}{A_2} - \frac{1}{{{\tau _{12}}}}{A_2} + \frac{1}{{{\tau _{12}}}}{A_1}$$

The case of asymmetric coupling between resonances 1 and 2, with energy coupling from resonance 1 to resonance 2, was also investigated with corresponding rate equations:

$$\frac{{d{A_1}}}{{dt}} ={-} i{\omega _{01}}{A_1} - \frac{1}{{{\tau _{11w}}}}{A_1} - \frac{1}{{{\tau _{12w}}}}{A_1} - \frac{1}{{{\tau _{12}}}}{A_1}$$
$$\frac{{d{A_2}}}{{dt}} ={-} i{\omega _{02}}{A_2} - \frac{1}{{{\tau _{21w}}}}{A_2} - \frac{1}{{{\tau _{22w}}}}{A_2} + \frac{1}{{{\tau _{12}}}}{A_1}\; $$

A schematic corresponding to the system is provided in Fig. 3. The solution for the symmetrically coupled resonances involves a second order differential equation. It yields the following roots:

$$\begin{aligned}{r_{1,2}} &= \frac{{ - i({{\omega_{01}} + {\omega_{02}}} )- \left( {\frac{1}{{{\tau_{11w}}}} + \frac{1}{{{\tau_{12w}}}} + \frac{1}{{{\tau_{21w}}}} + \frac{1}{{{\tau_{22w}}}} + \frac{2}{{{\tau_{12}}}}} \right)}}{2}\\ &\quad \pm \frac{{\sqrt {{{\left[ {i({{\omega_{01}} - {\omega_{02}}} )+ \left( {\frac{1}{{{\tau_{11w}}}} + \frac{1}{{{\tau_{12w}}}} - \frac{1}{{{\tau_{21w}}}} - \frac{1}{{{\tau_{22w}}}}} \right)} \right]}^2} + {{\left( {\frac{2}{{{\tau_{12}}}}} \right)}^2}} }}{2}\end{aligned}$$

The coupling term, ${\tau _{12}}$, was found by matching the field amplitude ${A_1}$ with our post-implant experimental spectral measurement results shown in Fig. 4, and was found to equal 647.5 ps. The solution for the asymmetrically coupled resonances contains a single exponential term:

$${r_1} ={-} i{\omega _{01}} - \left( {\frac{1}{{{\tau_{11w}}}} + \frac{1}{{{\tau_{12w}}}} + \frac{1}{{{\tau_{12}}}}} \right)\; $$

 figure: Fig. 3.

Fig. 3. Schematic diagram showing the essential features of our coupled-mode theory model: two single-mode waveguides 1, and 2, with output field amplitudes ${{\boldsymbol s}_{\mathbf{1},\mathbf{2} - }}$; two resonances of field amplitudes ${{\boldsymbol A}_{\mathbf{1},\mathbf{2}}}$ and fequencies ${{\boldsymbol \omega }_{\mathbf{01},\mathbf{02}}}$ coupled to waveguides 1 and 2, and one another with lifetimes ${{\boldsymbol t}_{\mathbf{11}{\boldsymbol w}}}$, ${{\boldsymbol t}_{\mathbf{12}{\boldsymbol w}}}$, ${{\boldsymbol t}_{\mathbf{21}{\boldsymbol w}}}$, ${{\boldsymbol t}_{\mathbf{22}{\boldsymbol w}}}$, and ${{\boldsymbol t}_{\mathbf{12}}}$. ${{\boldsymbol s}_{\mathbf{1},\mathbf{2} - }}$ are normalized so that ${|{{{\boldsymbol s}_{\mathbf{1},\mathbf{2} - }}} |^{\mathbf 2}}$ is power in the waveguide, and ${{\boldsymbol A}_{\mathbf{1},\mathbf{2}}}$ are normalized so that ${|{{{\boldsymbol A}_{\mathbf{1},\mathbf{2}}}} |^{\mathbf 2}}$ is energy in the cavities.

Download Full Size | PPT Slide | PDF

 figure: Fig. 4.

Fig. 4. Photoluminescence spectrum of post-implant color centers (blue) with Voigt profile generated by coupled-mode system of equations overlaid in grey. A good match between our experiment and theoretical analysis is achieved by considering inhomogeneous broadening effects, specifically strain broadening, within the diamond sample.

Download Full Size | PPT Slide | PDF

As in the symmetrically coupled regime, ${\tau _{12}}$ was found to equal 647.5ps. Therefore, we cannot use the decay rate alone to distinguish between the symmetric and asymmetric descriptions.

The decay rate and field amplitude ${A_1}$, when evaluated in the symmetric and asymmetric coupling frameworks, showed a good match with the bulk lifetime decay and intensity measured in our post-implant color centers. The spectral data was also considered. Our measured spectral intensity shown in Fig. 4 features a strong peak at 624 nm that likely results from inhomogeneous broadening, or vibrionic broadening as measured in previous experiments involving NVs [32]. Also, of note is the absence of the zero phonon line. The zero-phonon line of NV centers is not directly measured for nanodiamonds of the size and agglomeration pattern reported in our work. For this information, please see work specializing in this topic, such as Ref. [33]. In both cases of inhomogeneous broadening or vibrionic broadening, we would expect a Gaussian broadening to be induced by the presence of these phenomena. To investigate this, our coupled-mode system of equations was solved in the frequency domain. In both coupling frameworks, this output features two Lorentzian peaks with linewidths less than 1 nm, corresponding to two resonances with peaks at 637 nm and 811 nm. These were then convolved with a single Gaussian with standard deviation of 85 nm, representing inhomogeneous broadening effects, and the resulting Voigt profiles generated for both coupling frameworks shows a good match with our measured results. A Voight profile results from the convolution of two broadening mechanisms, one which would produce a Gaussian profile, typically inhomogeneous broadening, and the other would produce a Lorentzian profile, likely homogeneous broadening. Voigt profiles are common in many branches of spectroscopy.

It is a fair assumption that inhomogeneous broadening effects are prevalent throughout our sample and contribute to the observed lineshape. Nanodiamonds feature several defects with a range of surface functionalizations [34]. These defects give rise to strain broadening, which is an inhomogeneous broadening effect arising from differences in the local environment of emitters at different spatial locations [35]. This Voigt profile generation method has been used previously to describe other diamond color center species, specifically silicon-vacancy color centers [35] where inhomogeneous distributions have also been observed. Therefore, it can be concluded that the observed lineshape is predicted by our coupled-mode analysis. Another explanation may involve vibrational broadening effects observed in previous experiments involving NVs [32]. Vibrational transitions, and their associated lineshape broadening, could also be responsible for our observed photoluminescence spectra. The distinction between these two hypotheses is not resolved by either the time-domain or frequency-domain data, and thus will require additional investigation in future work.

From our results, it appears the coupling of nitrogen-vacancy color centers and xenon color centers within nanodiamonds gives rise to an overall lifetime reduction. This reduction in lifetime is not accompanied by a reduction in intensity, as is typical of shunting effects due to nitrogen-vacancies coupling to other lattice defects, such as C-centers and A-centers. Instead, we observe an almost two-fold increase in intensity. Coupled-mode theory provides a suitable explanation for these effects.

5. Conclusions

In conclusion, we have shown that the implantation of xenon into nanodiamonds and subsequent annealing gives rise to an increase in color center intensity as well as a reduction in color center lifetime. Our measured pre-implant lifetime was 550ps, while our measured post-implant lifetime was 297 ps. This corresponds to a lifetime reduction of 46%. We employed coupled-mode theory to determine that this lifetime reduction is consistent with a coupling between the nitrogen-vacancy and xenon color centers in the bulk, corresponding to a coupling time constant of 647.5 ps. These parameters were also consistent with the observed spectral lineshape, described by a Voigt profile with two Lorentzian peaks at 637 nm and 811 nm that is convolved with a single Gaussian reflecting inhomogeneous broadening effects.

Our method of lifetime shortening lacks many of the drawbacks of other conventional methods, such as a decrease in emitter intensity and difficult fabrication requiring specialized equipment prone to user error. Instead, quantum emitters produced with our method feature increased emitter intensity and simpler fabrication. While prior literature has established that NV centers can be used as single photon emitters, and lifetime shortening may enable faster single photon emission, the measurement technique employed did not allow for 2-photon correlation measurement. Therefore, additional studies are warranted to examine this correlation. Regardless, ion implantation and subsequent annealing serves as an attractive option for the fabrication of room-temperature quantum emitters.

Funding

Office of Naval Research (N000014-15-1-2833, N00014-19-S-B001); National Science Foundation (CBET-1855882, EEC-1227110, EEC1454315-CAREER); U.S. Department of Energy (DEEE0004946).

Acknowledgements

All implantation was performed by Sandia National Laboratories. Photoluminescence spectroscopy materials and equipment were provided by Professor Vladmir Shalaev’s group at Purdue University’s Birck Nanotechnology Center with experiments conducted and overseen by Simeon Bogdanov.

Disclosures

The authors declare no conflicts of interest.

Data availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

Supplemental document

See Supplement 1 for supporting content.

References

1. T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005). [CrossRef]  

2. I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016). [CrossRef]  

3. N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016). [CrossRef]  

4. Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013). [CrossRef]  

5. R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020). [CrossRef]  

6. A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014). [CrossRef]  

7. A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012). [CrossRef]  

8. E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018). [CrossRef]  

9. W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015). [CrossRef]  

10. D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013). [CrossRef]  

11. T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017). [CrossRef]  

12. L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014). [CrossRef]  

13. F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011). [CrossRef]  

14. A. M. Zaitsev, Optical Properties of Diamond A Data Handbook (Springer, 2001).

15. M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013). [CrossRef]  

16. Olev. Sild and Kristjan. Haller, Zero-Phonon Lines And Spectral Hole Burning in Spectroscopy and Photochemistry (Springer, 1988).

17. C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000). [CrossRef]  

18. R. Brouri, A. Beveratos, J.-P. Poizat, and P. Grangier, “Photon antibunching in the fluorescence of individual color centers in diamond,” Opt. Lett. 25(17), 1294–1296 (2000). [CrossRef]  

19. A. Dräbenstedt and F. Jelezko, “Low-temperature microscopy and spectroscopy on single defect centers in diamond,” Phys. Rev. B 60(16), 11503–11508 (1999). [CrossRef]  

20. Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

21. R. Okubo, M. Hirano, Y. Zhang, and T. Hirano, “Pulse-resolved measurement of quadrature phase amplitudes of squeezed pulse trains at a repetition rate of 76 MHz,” Opt. Lett. 33(13), 1458–1460 (2008). [CrossRef]  

22. A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015). [CrossRef]  

23. C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019). [CrossRef]  

24. T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010). [CrossRef]  

25. P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007). [CrossRef]  

26. P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017). [CrossRef]  

27. P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018). [CrossRef]  

28. V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).

29. Q. Li, T. Wang, Y. Su, M. Yan, and M. Qiu, “Coupled mode theory analysis of mode-splitting in coupled cavity system,” Opt. Express 18(8), 8367–8382 (2010). [CrossRef]  

30. W. Huang, “Coupled-Mode Theory,” Open Research Library 19(10), 1505–1518 (1991).

31. M. Popovic, C. Manolatou, and M. Watts, “Coupling-induced resonance frequency shifts in coupled dielectric multi-cavity filters,” Opt. Express 14(3), 1208–1222 (2006). [CrossRef]  

32. M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013). [CrossRef]  

33. M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016). [CrossRef]  

34. V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012). [CrossRef]  

35. S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018). [CrossRef]  

References

  • View by:

  1. T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
    [Crossref]
  2. I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016).
    [Crossref]
  3. N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
    [Crossref]
  4. Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
    [Crossref]
  5. R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
    [Crossref]
  6. A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
    [Crossref]
  7. A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
    [Crossref]
  8. E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
    [Crossref]
  9. W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
    [Crossref]
  10. D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
    [Crossref]
  11. T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
    [Crossref]
  12. L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
    [Crossref]
  13. F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
    [Crossref]
  14. A. M. Zaitsev, Optical Properties of Diamond A Data Handbook (Springer, 2001).
  15. M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
    [Crossref]
  16. Olev. Sild and Kristjan. Haller, Zero-Phonon Lines And Spectral Hole Burning in Spectroscopy and Photochemistry (Springer, 1988).
  17. C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
    [Crossref]
  18. R. Brouri, A. Beveratos, J.-P. Poizat, and P. Grangier, “Photon antibunching in the fluorescence of individual color centers in diamond,” Opt. Lett. 25(17), 1294–1296 (2000).
    [Crossref]
  19. A. Dräbenstedt and F. Jelezko, “Low-temperature microscopy and spectroscopy on single defect centers in diamond,” Phys. Rev. B 60(16), 11503–11508 (1999).
    [Crossref]
  20. Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).
  21. R. Okubo, M. Hirano, Y. Zhang, and T. Hirano, “Pulse-resolved measurement of quadrature phase amplitudes of squeezed pulse trains at a repetition rate of 76 MHz,” Opt. Lett. 33(13), 1458–1460 (2008).
    [Crossref]
  22. A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
    [Crossref]
  23. C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
    [Crossref]
  24. T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
    [Crossref]
  25. P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007).
    [Crossref]
  26. P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
    [Crossref]
  27. P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
    [Crossref]
  28. V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).
  29. Q. Li, T. Wang, Y. Su, M. Yan, and M. Qiu, “Coupled mode theory analysis of mode-splitting in coupled cavity system,” Opt. Express 18(8), 8367–8382 (2010).
    [Crossref]
  30. W. Huang, “Coupled-Mode Theory,” Open Research Library 19(10), 1505–1518 (1991).
  31. M. Popovic, C. Manolatou, and M. Watts, “Coupling-induced resonance frequency shifts in coupled dielectric multi-cavity filters,” Opt. Express 14(3), 1208–1222 (2006).
    [Crossref]
  32. M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
    [Crossref]
  33. M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
    [Crossref]
  34. V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
    [Crossref]
  35. S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
    [Crossref]

2020 (1)

R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
[Crossref]

2019 (1)

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

2018 (3)

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

2017 (2)

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

2016 (3)

I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016).
[Crossref]

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

2015 (2)

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
[Crossref]

2014 (2)

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

2013 (4)

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
[Crossref]

2012 (2)

V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
[Crossref]

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

2011 (1)

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

2010 (2)

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Q. Li, T. Wang, Y. Su, M. Yan, and M. Qiu, “Coupled mode theory analysis of mode-splitting in coupled cavity system,” Opt. Express 18(8), 8367–8382 (2010).
[Crossref]

2008 (1)

2007 (1)

P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007).
[Crossref]

2006 (1)

2005 (1)

T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
[Crossref]

2000 (2)

C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
[Crossref]

R. Brouri, A. Beveratos, J.-P. Poizat, and P. Grangier, “Photon antibunching in the fluorescence of individual color centers in diamond,” Opt. Lett. 25(17), 1294–1296 (2000).
[Crossref]

1999 (1)

A. Dräbenstedt and F. Jelezko, “Low-temperature microscopy and spectroscopy on single defect centers in diamond,” Phys. Rev. B 60(16), 11503–11508 (1999).
[Crossref]

1991 (1)

W. Huang, “Coupled-Mode Theory,” Open Research Library 19(10), 1505–1518 (1991).

Abel, B.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Aharonovich, I.

I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016).
[Crossref]

Almeida, M. P.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Anton, C.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Atatüre, M.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Auffeves, A.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Awschalom, D.

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

Baburin, Alexandr S.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Balasubramanian, G.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Barnard, A. S.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Barrett, S. D.

T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
[Crossref]

Bartholomew, J. G.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Bassett, L.

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

Becher, C.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Bernien, H.

W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
[Crossref]

Bettinelli, M.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Beveratos, A.

Bogdanov, Simeon I.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Boltasseva, Alexandra

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Bommer, A.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Bradac, C.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Brouri, R.

Brown, L. J.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Budker, D.

M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
[Crossref]

Capeli, M.

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Cavalli, E.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Cheng, C.-L.

P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007).
[Crossref]

Chiang, Chin-Cheng

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Chu, Y.

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Chung, K.

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Chung, P.-H.

P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007).
[Crossref]

Craiciu, I.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Dadgostar, S.

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

De Santis, L.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Delaney, P.

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

Demory, J.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Denisenko, A.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Doherty, M. W.

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Dolde, F.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Dräbenstedt, A.

A. Dräbenstedt and F. Jelezko, “Low-temperature microscopy and spectroscopy on single defect centers in diamond,” Phys. Rev. B 60(16), 11503–11508 (1999).
[Crossref]

Dzurak, A.

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

Englund, D.

I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016).
[Crossref]

Fedder, H.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Field, M. R.

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Fischer, K. A.

R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
[Crossref]

Fleming, G. R.

M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
[Crossref]

Fu, K.-M. C.

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

Gaebel, T.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Gali, A.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Gao, W. B.

W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
[Crossref]

Gibson, B. C.

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Giesz, V.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Gines, L.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Gogotsi, Y.

V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
[Crossref]

Goldman, M. L.

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Gomez, C.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Gorokhovsky, A. A.

V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).

Gould, M.

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

Grange, T.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Grangier, P.

Greentree, A. D.

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Griebel, J.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Haller, Kristjan.

Olev. Sild and Kristjan. Haller, Zero-Phonon Lines And Spectral Hole Burning in Spectroscopy and Photochemistry (Springer, 1988).

Hanson, R.

W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
[Crossref]

Hatami, F.

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

He, Y.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

He, Y. M.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Hingant, T.

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Hirano, M.

Hirano, T.

Ho, D.

V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
[Crossref]

Höfling, S.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Hollenberg, L. C. L.

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Hornecker, G.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Hu, E.

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

Huang, W.

W. Huang, “Coupled-Mode Theory,” Open Research Library 19(10), 1505–1518 (1991).

Huxter, M.

M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
[Crossref]

Imamoglu, A.

W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
[Crossref]

Isoya, J.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

Jacques, V.

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Jahnke, K. D.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

Jelezko, F.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

A. Dräbenstedt and F. Jelezko, “Low-temperature microscopy and spectroscopy on single defect centers in diamond,” Phys. Rev. B 60(16), 11503–11508 (1999).
[Crossref]

Jeske, J.

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Kahnt, A.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Kamp, M.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Karle, T. J.

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Khalid, A.

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Kildishev, Alexander V.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Kim, S.

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

Kindem, J. M.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Knolle, W.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Kok, P.

T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
[Crossref]

Krueger, A.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Kubanek, A.

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Kurtsiefer, C.

C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
[Crossref]

Lagutchev, Alexei S.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Lanco, L.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Lanzillotti-Kimura, N. D.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Lau, D. W.

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Lau, D. W. M.

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Laube, C.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Lehnert, J.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Lemaitre, A.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Li, Q.

Lindner, S.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Londero, E.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Loredo, J. C.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Lu, C. Y.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Lukin, M. D.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Luo, H.

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

Makarova, Oksana A.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Maletinsky, P.

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Mandal, S.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Manolatou, C.

Manson, N. B.

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

Markham, M.

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Marsili, F.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Martinovich, V. A.

V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).

Mayer, S.

C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
[Crossref]

Meijer, J.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Miyazono, E.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Mochalin, V. N.

V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
[Crossref]

Müller, K.

R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
[Crossref]

Munro, W. J.

T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
[Crossref]

Muzha, A.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Naidoo, N.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Nam, S. W.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Nobauer, T.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Nunn, N.

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

Oeckinghaus, T.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

Ohshima, T.

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Okubo, R.

Oliver, T. A. A.

M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
[Crossref]

Pan, J. W.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Perevedentseva, E.

P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007).
[Crossref]

Petta, J.

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

Plakhotnik, T.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Poizat, J.-P.

Popovic, M.

Portalupi, S. L.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Qiu, M.

Rabeau, J. R.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Rajasekharan, R.

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Reineck, P.

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Reinhard, F.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Rempp, F.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Roch, J.-F.

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Rochman, J.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Rodionov, Ilya A.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Rogers, L.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

Rondin, L.

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Ryzhikov, Ilya A.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Sagnes, I.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Saha, Soham

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Schmidgall, E. R.

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

Schneider, C.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Sellars, M. J.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Senellart, P.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Shah, Deesha

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Shalaev, Vladimir M.

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Shenderova, O.

V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
[Crossref]

Shenderova, O. A.

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

Sild, Olev.

Olev. Sild and Kristjan. Haller, Zero-Phonon Lines And Spectral Hole Burning in Spectroscopy and Photochemistry (Springer, 1988).

Sipahigil, A.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Solomon, Z.

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

Somaschi, N.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Spiller, T. P.

T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
[Crossref]

Su, Y.

Sun, E.

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

Teraji, T.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

Tetienne, J.-P.

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Togan, E.

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Tomljenovic-Hanic, S.

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Toth, M.

I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016).
[Crossref]

Trivedi, R.

R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
[Crossref]

Turukhin, A. V.

V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).

Twamley, J.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Twitchen, D. J.

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Verma, V.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Vuckovic, J.

R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
[Crossref]

Waks, G. S.

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

Wang, T.

Watts, M.

Wei, Y. J.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Weinfurter, H.

C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
[Crossref]

White, A. G.

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

Williams, O.

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Wilson, E. R.

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

Wolf, T.

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Wrachtrup, J.

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

Wu, D.

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Yan, M.

Zaitsev, A. M.

V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).

A. M. Zaitsev, Optical Properties of Diamond A Data Handbook (Springer, 2001).

Zarda, P.

C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
[Crossref]

Zhang, Y.

Zhong, T.

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Zibrov, A. S.

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

Zvyagin, A. V.

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

Adv. Quantum Technol. (1)

R. Trivedi, K. A. Fischer, J. Vučković, and K. Müller, “Generation of Non-Classical Light Using Semiconductor Quantum Dots,” Adv. Quantum Technol. 3(1), 1900007 (2020).
[Crossref]

Contemp. Phys. (1)

T. P. Spiller, W. J. Munro, S. D. Barrett, and P. Kok, “An introduction to quantum information processing: applications and realizations,” Contemp. Phys. 46(6), 407–436 (2005).
[Crossref]

EPJ Web Conf. (1)

M. Huxter, T. A. A. Oliver, D. Budker, and G. R. Fleming, “Vibrational and electronic ultrafast relaxation of the nitrogen-vacancy centers in diamond,” EPJ Web Conf. 41, 04009–8 (2013).
[Crossref]

Nanoscale (2)

C. Laube, T. Oeckinghaus, J. Lehnert, J. Griebel, W. Knolle, A. Denisenko, A. Kahnt, J. Meijer, J. Wrachtrup, and B. Abel, “Controlling the fluorescence properties of nitrogen vacancy centers in nanodiamonds,” Nanoscale 11(4), 1770–1783 (2019).
[Crossref]

P. Reineck, M. Capeli, D. W. Lau, J. Jeske, M. R. Field, T. Ohshima, A. D. Greentree, and B. C. Gibson, “Bright and photostable nitrogen-vacancy fluorescence from unprocessed detonation nanodiamond,” Nanoscale 9(2), 497–502 (2017).
[Crossref]

Nat. Nanotechnol. (3)

T. Gaebel, M. J. Sellars, A. S. Barnard, L. J. Brown, C. Bradac, N. Naidoo, J. R. Rabeau, J. Twamley, T. Plakhotnik, and A. V. Zvyagin, “Observation and control of blinking nitrogen-vacancy centres in discrete nanodiamonds,” Nat. Nanotechnol. 5(5), 345–349 (2010).
[Crossref]

V. N. Mochalin, O. Shenderova, D. Ho, and Y. Gogotsi, “The properties and applications of nanodiamonds,” Nat. Nanotechnol. 7(1), 11–23 (2012).
[Crossref]

Y. M. He, Y. He, Y. J. Wei, D. Wu, M. Atatüre, C. Schneider, S. Höfling, M. Kamp, C. Y. Lu, and J. W. Pan, “On-demand semiconductor single-photon source with near-unity indistinguishability,” Nat. Nanotechnol. 8(3), 213–217 (2013).
[Crossref]

Nat. Photonics (3)

I. Aharonovich, D. Englund, and M. Toth, “Solid-state single-photon emitters,” Nat. Photonics 10(10), 631–641 (2016).
[Crossref]

N. Somaschi, V. Giesz, L. De Santis, J. C. Loredo, M. P. Almeida, G. Hornecker, S. L. Portalupi, T. Grange, C. Anton, J. Demory, C. Gomez, I. Sagnes, N. D. Lanzillotti-Kimura, A. Lemaitre, A. Auffeves, A. G. White, L. Lanco, and P. Senellart, “Near optimal single photon sources in the solid state,” Nat. Photonics 10(5), 340–345 (2016).
[Crossref]

W. B. Gao, A. Imamoglu, H. Bernien, and R. Hanson, “Coherent manipulation, measurement and entanglement of individual solid-state spins using optical fields,” Nat. Photonics 9(6), 363–373 (2015).
[Crossref]

Nat. Phys. (1)

F. Dolde, H. Fedder, M. W. Doherty, T. Nobauer, F. Rempp, G. Balasubramanian, T. Wolf, F. Reinhard, L. C. L. Hollenberg, F. Jelezko, and J. Wrachtrup, “Electric-field sensing using single diamond spins,” Nat. Phys. 7(6), 459–463 (2011).
[Crossref]

New J. Phys. (1)

S. Lindner, A. Bommer, A. Muzha, A. Krueger, L. Gines, S. Mandal, O. Williams, E. Londero, A. Gali, and C. Becher, “Strongly inhomogeneous distribution of spectral properties of silicon-vacancy color centers in nanodiamonds,” New J. Phys. 20(11), 115002 (2018).
[Crossref]

Open Research Library (1)

W. Huang, “Coupled-Mode Theory,” Open Research Library 19(10), 1505–1518 (1991).

Opt. Express (2)

Opt. Lett. (2)

Phys. Rep. (1)

M. W. Doherty, N. B. Manson, P. Delaney, F. Jelezko, J. Wrachtrup, and L. C. L. Hollenberg, “The nitrogen-vacancy colour centre in diamond,” Phys. Rep. 528(1), 1–45 (2013).
[Crossref]

Phys. Rev. Appl. (1)

M. Gould, E. R. Schmidgall, S. Dadgostar, F. Hatami, and K.-M. C. Fu, “Efficient Extraction of Zero-Phonon-Line Photons from Single Nitrogen-Vacancy Centers in an Integrated GaP-on-Diamond Platform,” Phys. Rev. Appl. 6(1), 011001 (2016).
[Crossref]

Phys. Rev. B (1)

A. Dräbenstedt and F. Jelezko, “Low-temperature microscopy and spectroscopy on single defect centers in diamond,” Phys. Rev. B 60(16), 11503–11508 (1999).
[Crossref]

Phys. Rev. Lett. (3)

A. Sipahigil, K. D. Jahnke, L. Rogers, T. Teraji, J. Isoya, A. S. Zibrov, F. Jelezko, and M. D. Lukin, “Indistinguishable photons from separated silicon-vacancy centers in diamond,” Phys. Rev. Lett. 113(11), 113602 (2014).
[Crossref]

A. Sipahigil, M. L. Goldman, E. Togan, Y. Chu, M. Markham, D. J. Twitchen, A. S. Zibrov, A. Kubanek, and M. D. Lukin, “Quantum interference of single photons from remote nitrogen-vacancy centers in diamond,” Phys. Rev. Lett. 108(14), 143601 (2012).
[Crossref]

C. Kurtsiefer, S. Mayer, P. Zarda, and H. Weinfurter, “Stable solid-state source of single photons,” Phys. Rev. Lett. 85(2), 290–293 (2000).
[Crossref]

Rep. Prog. Phys. (1)

L. Rondin, J.-P. Tetienne, T. Hingant, J.-F. Roch, P. Maletinsky, and V. Jacques, “Magnetometry with nitrogen-vacancy defects in diamond,” Rep. Prog. Phys. 77(5), 056503 (2014).
[Crossref]

Sci. Rep. (2)

P. Reineck, D. W. M. Lau, E. R. Wilson, N. Nunn, O. A. Shenderova, and B. C. Gibson, “Visible to near-IR fluorescence from single-digit detonation nanodiamonds: Excitation wavelength and pH dependence,” Sci. Rep. 8(1), 2478 (2018).
[Crossref]

A. Khalid, K. Chung, R. Rajasekharan, D. W. M. Lau, T. J. Karle, B. C. Gibson, and S. Tomljenovic-Hanic, “Lifetime reduction and enhanced emission of single photon color centers in nanodiamond via surrounding refractive index modification,” Sci. Rep. 5(1), 11179 (2015).
[Crossref]

Science (3)

E. Sun, S. Kim, H. Luo, Z. Solomon, and G. S. Waks, “Quantum memory,” Science 361(6397), 57–60 (2018).
[Crossref]

D. Awschalom, L. Bassett, A. Dzurak, E. Hu, and J. Petta, “Quantum Spintronics: Engineering and Manipulating Atom-Like Spins in Semiconductors,” Science 339(6124), 1174–1179 (2013).
[Crossref]

T. Zhong, J. M. Kindem, J. G. Bartholomew, J. Rochman, I. Craiciu, E. Miyazono, M. Bettinelli, E. Cavalli, V. Verma, S. W. Nam, and F. Marsili, “Nanophotonic rare-earth quantum memory with optically controlled retrieval,” Science 357(6358), 1392–1395 (2017).
[Crossref]

Surf. Sci. (1)

P.-H. Chung, E. Perevedentseva, and C.-L. Cheng, “The particle size-dependent photoluminescence of nanodiamonds,” Surf. Sci. 601(18), 3866–3870 (2007).
[Crossref]

Other (4)

V. A. Martinovich, A. V. Turukhin, A. M. Zaitsev, and A. A. Gorokhovsky, “Photoluminescence spectra of xenon implanted natural diamonds,” in Journal of Luminescence 102-103, 785–790 (2003).

A. M. Zaitsev, Optical Properties of Diamond A Data Handbook (Springer, 2001).

Simeon I. Bogdanov, Oksana A. Makarova, Alexei S. Lagutchev, Deesha Shah, Chin-Cheng Chiang, Soham Saha, Alexandr S. Baburin, Ilya A. Ryzhikov, Ilya A. Rodionov, Alexander V. Kildishev, Alexandra Boltasseva, and Vladimir M. Shalaev, “Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas,” ArXiV:1902.05996 (2019).

Olev. Sild and Kristjan. Haller, Zero-Phonon Lines And Spectral Hole Burning in Spectroscopy and Photochemistry (Springer, 1988).

Supplementary Material (1)

NameDescription
Supplement 1       Description of SAUD process and Optical experiment

Data availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

Cited By

Optica participates in Crossref's Cited-By Linking service. Citing articles from Optica Publishing Group journals and other participating publishers are listed here.

Alert me when this article is cited.


Figures (4)

Fig. 1.
Fig. 1. Process flow diagram for Xe color center fabrication. a.) A nanodiamond film is deposited using disaggregated nanodiamonds in solution via electrophoretic deposition prior to ion implantation. b.) The resultant film is characterized via scanning electron microscopy and reveals good surface coverage. c.) The resulting film is implanted with Xe species at a fluence of ${\mathbf{10^{14}}}$ ${\textbf {ions}}/{\textbf c}{{\textbf m}^2}$; the resulting color centers are characterized via scanning photoluminescent (PL) spectroscopy (this image has a field of view of 20 × 20 µm2).
Fig. 2.
Fig. 2. Lifetime measurements are conducted on pre-implant (gray) and post-implant (blue) color center species. Pre-Implant and post-implant data is represented by the grey and black circles, respectively. Post-Implant color centers show a bulk lifetime of ${{\boldsymbol \tau }_\mathbf 2} = $297${\pm} {\mathbf{10}}$ ps. This is a 43% reduction in bulk lifetime compared to pre-implant color centers. The sharp decline in the pre-implant data is due to the higher contribution of surface effects (${{\boldsymbol \tau }_1} = $ 38${\pm} {\mathbf 8}$ ps) in the observed fluorescence.
Fig. 3.
Fig. 3. Schematic diagram showing the essential features of our coupled-mode theory model: two single-mode waveguides 1, and 2, with output field amplitudes ${{\boldsymbol s}_{\mathbf{1},\mathbf{2} - }}$; two resonances of field amplitudes ${{\boldsymbol A}_{\mathbf{1},\mathbf{2}}}$ and fequencies ${{\boldsymbol \omega }_{\mathbf{01},\mathbf{02}}}$ coupled to waveguides 1 and 2, and one another with lifetimes ${{\boldsymbol t}_{\mathbf{11}{\boldsymbol w}}}$, ${{\boldsymbol t}_{\mathbf{12}{\boldsymbol w}}}$, ${{\boldsymbol t}_{\mathbf{21}{\boldsymbol w}}}$, ${{\boldsymbol t}_{\mathbf{22}{\boldsymbol w}}}$, and ${{\boldsymbol t}_{\mathbf{12}}}$. ${{\boldsymbol s}_{\mathbf{1},\mathbf{2} - }}$ are normalized so that ${|{{{\boldsymbol s}_{\mathbf{1},\mathbf{2} - }}} |^{\mathbf 2}}$ is power in the waveguide, and ${{\boldsymbol A}_{\mathbf{1},\mathbf{2}}}$ are normalized so that ${|{{{\boldsymbol A}_{\mathbf{1},\mathbf{2}}}} |^{\mathbf 2}}$ is energy in the cavities.
Fig. 4.
Fig. 4. Photoluminescence spectrum of post-implant color centers (blue) with Voigt profile generated by coupled-mode system of equations overlaid in grey. A good match between our experiment and theoretical analysis is achieved by considering inhomogeneous broadening effects, specifically strain broadening, within the diamond sample.

Equations (6)

Equations on this page are rendered with MathJax. Learn more.

dA1dt=iω01A11τ11wA11τ12wA11τ12A1+1τ12A2
dA2dt=iω02A21τ21wA21τ22wA21τ12A2+1τ12A1
dA1dt=iω01A11τ11wA11τ12wA11τ12A1
dA2dt=iω02A21τ21wA21τ22wA2+1τ12A1
r1,2=i(ω01+ω02)(1τ11w+1τ12w+1τ21w+1τ22w+2τ12)2±[i(ω01ω02)+(1τ11w+1τ12w1τ21w1τ22w)]2+(2τ12)22
r1=iω01(1τ11w+1τ12w+1τ12)

Metrics

Select as filters


Select Topics Cancel
© Copyright 2022 | Optica Publishing Group. All Rights Reserved