Abstract
The application of masers is limited by its demanding working conditions (high vacuum or low temperature). A room-temperature solid-state maser is highly desirable, but the lifetimes of emitters (electron spins) in solids at room temperature are usually too short (∼ns) for population inversion. Masing from pentacene spins in p-terphenyl crystals, which have a long spin lifetime (∼0.1 ms), has been demonstrated. This maser, however, operates only in the pulsed mode. Here we propose a room-temperature maser based on nitrogen-vacancy centres in diamond, which features the longest known solid-state spin lifetime (∼5 ms) at room temperature, high optical pumping efficiency (∼106 s−1) and material stability. Our numerical simulation demonstrates that a maser with a coherence time of approximately minutes is feasible under readily accessible conditions (cavity Q-factor ∼5 × 104, diamond size ∼3 × 3 × 0.5 mm3 and pump power <10 W). A room-temperature diamond maser may facilitate a broad range of microwave technologies.
Similar content being viewed by others
Introduction
The maser1—with a frequency 0.3–300 GHz and a wavelength between 1 m and 1 mm—is the microwave analogue of lasers with several important applications2,3,4,5 such as in ultrasensitive magnetic resonance spectroscopy, astronomy observation, space communication, radar and high-precision clocks. Such applications, however, are hindered by the demanding operation conditions (high vacuum for a gas maser6 and liquid-helium temperature for a solid-state maser7). Room-temperature solid-state masers are highly desirable.
The key to a maser is the population inversion of the emitters and the macroscopic coherence among microwave photons. Population inversion requires a spin relaxation rate lower than the pump rate. This sets the bottleneck in room-temperature solid-state masers, as the spin relaxation times in solids are usually extremely short (approximately nanoseconds8) at room temperature due to rapid phonon scattering7. The spin relaxation induced by phonon scattering can be largely suppressed in light-element materials (such as organic materials) where the spin–orbit coupling is weak. Actually, the only room-temperature solid-state maser demonstrated so far is based on a pentacene-doped p-terphenyl molecular crystal where the spin lifetime can reach 135 μs at room temperature9. However, the active spins in pentacene-doped p-terphenyl are the intermediate metastable states instead of the ground states. Such an energy level structure greatly reduces the optical pumping efficiency and the pentacene maser requires high pump laser power. In addition, the organic material of p-terphenyl molecular crystal is unstable under high-power pump and at high temperature. The pentacence maser works only at the pulsed mode with a quite low repetition rate (∼1 Hz)9. Another candidate system under consideration is the silicon vacancy (VSi) centre in silicon carbide10. Very recently, it has been clarified that the VSi centre has a spin-3/2 ground state, which allows population inversion by an optical pump10,11. The spin lifetime is quite long (∼0.5 ms) at room temperature10,11. Stimulated microwave emission from VSi centres has been observed at room temperature10. Masing from the silicon carbide spins, however, is still elusive. The challenges include the complexity of the defects in the compound material and the difficulty of engineering the VSi centres.
Nitrogen-vacancy (NV) centre spins in diamond12 have been extensively studied for quantum information processing12 and quantum sensing13,14,15. This is due to their long coherence time at room temperature and high efficiencies of initialization by optical pumping and readout via photon detection. In particular, coupling between ensemble NV centre electron spins and superconducting resonators has been demonstrated for quantum information storage and retrieval in hybrid quantum systems at cryogenic temperature16,17. Enhanced quantum coherence of NV centre ensembles has been observed in the strong coupling regime at low temperature18. It should be noted that the superb spin coherence features of NV centres persist at room temperature and even at temperatures up to at least 600 K (ref. 19), and the requirement of low temperatures in refs 16, 17, 18 is mostly for the resonators used. On the basis of these works, we here propose a new class of quantum technologies based on NV centres in diamond, namely, room-temperature solid-state masers and microwave amplifiers.
NV centres in diamond possess all of the features needed for a room-temperature solid-state maser. NV centre spins have the longest known lifetime (∼5 ms) at room temperature20,21,22 among all of the solid-state spins (∼50 times longer than ∼0.1 ms in pentacene-doped p-terphenyl9 and ∼10 times longer than ∼0.5 ms in silicon carbide10,11). The spin is a triplet (spin-1) in the ground state and it can be optically pumped rapidly to the ms=0 ground state, with a pump rate as high as ∼106 s−1 (refs 23, 24, 25, 26) (versus ∼103 to 105 s−1 in organic materials9 and ∼105 s−1 in silicon carbide27). Therefore, the population inversion can be easily achieved if a magnetic field is applied to shift the ms=0 ground state to above another spin state. Furthermore, the good thermal conductivity and material stability of diamond are also advantageous for masers. All of these features suggest that the NV centres in diamond are a superb gain medium for a room-temperature solid-state maser. However, the diamond maser requires a magnetic field; this is a further experimental complication that can, however, be overcome because magnets that can provide stable and uniform magnetic fields are commercially available28,29,30.
Here, we theoretically propose a room-temperature maser based on NV centres in diamond. Our numerical simulation demonstrates that masing and microwave amplification are feasible under readily accessible conditions (cavity Q-factor ∼50,000, diamond size ∼3 × 3 × 0.5 mm3 and NV centre concentration ∼2 p.p.m.), with the 532-nm optical pump threshold ∼3 W for microwave amplifying and ∼4 W for masing. For a pump power <10 W, it is feasible to achieve masing with an output power of >10 nW, a coherence time of approximately minutes, an mHz linewidth and a sensitivity of <10 pT Hz−1/2 for magnetometry application. As a room-temperature microwave amplifier, the noise temperature is as low as ∼0.3 K under a few-watt pump. A room-temperature diamond maser may facilitate a broad range of microwave technologies.
Results
System and model
We consider an ensemble of NV centre spins in diamond resonantly coupled to a high-quality microwave sapphire dielectric resonator cavity9,31 (Fig. 1a; Supplementary Note 1). This type of cavity has been experimentally demonstrated to have a Q-factor of >105 at room temperature9,31. Note that many other types of microwave resonators10,32 may also be considered for implementing the proposal in this paper. The spin sublevels (ms=0 or ms=±1) of the NV triplet ground state have a zero-field splitting about 2.87 GHz between and (ref. 12) (Fig. 1b). The NV centres can be optically pumped to the state (ref. 12). A moderate external magnetic field (>1,000 G) splits the states and shifts the state to below so that the spins can be inverted by an optical pump (Fig. 1b,c). The transition frequency ωS between the spin ground state and the spin exited state is tuned resonant with the microwave cavity frequency ωc.
The maser is driven by coupling between the cavity mode and the spins. The Hamiltonian of the coupled spin–cavity system is , where annihilates a microwave cavity photon, is the raising operator of the j-th spin, , and gj is the coupling constant. Without changing the essential results, we assume that the spin–photon coupling is uniform, that is, gj=g and write the Hamiltonian as with the collective operators , which satisfy the commutation relation . When masing occurs, the spin polarization (or population inversion) is a macroscopic number , while the fluctuation is much smaller. Therefore, can be interpreted as the creation operator of a collective mode with . The creation operator generates coherent superposition states in the spin ensemble. For example, from a fully polarized spin state, the collective mode state excited by one cavity photon is a quantized spin wave , which acts as a boson. In the masing state, both the photons and the spin collective modes, coherently coupled to each other, have macroscopic amplitudes. With the excitation number of the coherent spin collective mode , the spins are in a macroscopic quantum superposition state, which is maintained by the masing process.
A prerequisite of masing is the spin population inversion. The optical pumping rate w can be tuned by varying the pump light intensity, up to ∼106 s−1 (refs 23, 24, 25, 26). The cavity mode has a decay rate determined by the cavity Q-factor, κc=ωc/Q, due to photon leakage and coupling to the input/output channels. The decay of the spin collective mode is caused by various mechanisms. First, the spin relaxation (T1 process caused by phonon scattering and resonant interaction between spins) contributes a decay rate γeg=1/T1. Second, the individual spins experience local field fluctuations due to interaction with nuclear spins, coupling to other NV and nitrogen (P1) centre electron spins, and fluctuation of the zero-field splitting17. Such local field fluctuations induce random phases to individual spins, making the bright collective mode decay to other modes at a rate , where is the dephasing time of the spin ensemble. Finally, the optical pump of the NV centres, being incoherent, also induces the decay of the collective mode. The collective mode decay rate induced by the incoherent pump is qw, where q≈16 is an amplification factor of the contribution of pump rate w to the collective mode decay rate κS (see Supplementary Note 1), due to multiple pathways (Fig. 1c) of the pump process. The total decay rate of the collective mode is thus . The coupled quantum dynamics of the collective modes and the photons is described by the quantum Langevin equations33 for the photon and spin collective mode operators and , the spin populations , and polarization (see Methods and Supplementary Note 2).
For a specific system, we consider a single crystal bulk diamond of volume VNV=3 × 3 × 0.5 mm3 with a natural abundance (1.1%) of 13C nuclear spins, a P1 centre concentration of about 20 p.p.m. and an NV centre concentration of 2 p.p.m. (for N-to-NV− conversion efficiency 10%). Such parameters are extracted from the diamond used in ref. 17. The ensemble spin decoherence time is =0.4 μs (ref. 17) (see Supplementary Note 1). Considering the four orientations of NV centres and three nuclear spin states of 14N, the number of NV centres coupled to the cavity mode is estimated to be N=ρNVVNV/12=1.32 × 1014. The external magnetic field 2,100 G results in ωS/2π≈3 GHz. The microwave dielectric resonator has its TE01δ mode frequency resonant with the spin collective mode, that is, ωc=ωS. The cavity system (Fig. 1a) is composed of a cylindrical sapphire dielectric resonator (with radius r=15 mm and height h=16 mm), and a coaxial cylindrical cavity (with radius R=40 mm and height H=40 mm), placed inside a Halbach magnet array with a 50 (80)-mm inner (outer) radius, which provides the uniform magnetic field with inhomogeneity <0.01 G across the diamond size28,29. The coupling between the microwave photons and the NV centre spins is calculated to be g/2π≈0.02 Hz for the effective cavity mode volume9,34 Veff≈3 cm3. At room temperature (T=300 K), the phonon scattering dominates the spin relaxation and γeg≈200 s−1 (refs 20, 21, 22). The number of thermal photons inside the cavity is nth≈2,100 at room temperature.
Masing conditions
The quantum Langevin equations can be solved at steady-state masing. When masing occurs, the quantum operators can be approximated as their expectation values, that is, , , and . By dropping the small quantum fluctuations, we reduce the quantum Langevin equations to classical equations for the expectation values (see Methods and Supplementary Note 2). Under the resonant condition (ωc=ωS), the steady-state solution is
When the spin polarization Sz∼O(N), we have S+S−∼O(N2). From equation (3), the number of intracavity photons and consequently the output power , both scaling with the number of spins by N2.
The requirement that photon number leads to the masing condition
On one hand, the pump rate needs to be greater than the spin relaxation rate for population inversion (w>γeg). On the other hand, the cavity Q-factor has to be above a threshold
to have a sufficient number of photons for sustaining the macroscopic quantum coherence. A stronger spin–photon coupling (g), a smaller spin collective mode decay rate (κS) or a larger number of spins (N) can reduce this threshold cavity Q-factor (see Supplementary Note 1 for more discussions). The cavity Q-factor threshold is equivalent to the requirement that the spin collective mode decay rate κS should be kept below the maximal collective emission rate of photons 4Ng2/κc. Otherwise overpumping would fully polarize the spins, making the spin–spin correlation vanish (Sz→N and S−→0).
The emergence of macroscopic quantum coherence is evidenced by macroscopic values of the spin–spin correlation, the photon number and the spin collective mode amplitude, and the long coherence time in the masing region (Fig. 2b–d). We calculated these quantities by using the higher-order equations of the correlation functions (see Methods and Supplementary Note 2), which apply to both masing and incoherent emission. The spin polarization Sz, the microwave output power and the spin–spin correlation (shown in Fig. 2a–c) are consistent with the results obtained from equation (2) when the pump rate and the cavity Q-factor are above the masing threshold (white curve in the Fig. 2). It is clearly seen that the output power increases markedly when the pump rate is above the spin relaxation rate (population inverted) and when the cavity Q-factor is above the masing threshold (Q>QC) (Fig. 2b). The fact that unambiguously evidences the phase correlation among the large ensemble spins established by cavity photons in the masing region (Fig. 2c). The pump condition optimal for spin–spin correlation is determined by maximizing Under the condition that the pump is well above the threshold, , the spin–spin correlation reaches its maximum value at the optimal pump rate , where the spin polarization Sz≈N/2 and the maser power (see Supplementary Note 3).
The maser linewidth is determined by the correlation of the phase fluctuations of the photons or equivalently by that of the spin collective modes. The coherence time is obtained (see Supplementary Note 4) as
where is the photon number, is the spin collective mode number and nincoh=nth+Ne/Sz includes the thermal photon number (nth) and the incoherent spin collective mode number ( if the correlation between different spins is forced to be zero). The physical meaning of equation (6) is the following: the coherent excitations (photons and spin collective excitations) have the same phase within the total lifetime of the photons and the spin collective modes; beyond the total lifetime, each incoherent excitation induces a random phase ∼O(π); the total random phase is shared by all the coherent excitations. Thus the random phase of a single photon or spin collective excitation accumulated during the total lifetime is . The coherence time is greatly enhanced in the masing region (Fig. 2d). The spin collective mode decay rate of the NV centres κS>5 × 106 s−1, while for a good microwave cavity (Q∼105), the photon decay rate κc∼6π × 104 s−1, thus the photon number nc=nSκS/κc is much greater than the spin collective mode number, and the macroscopic quantum coherence is mainly maintained by the photons in the cavity. For readily accessible cavities in experiments, the fractional frequency instability of a room-temperature diamond maser is ∼10−12τ−1/2 as listed in Tables 1 and 2 for a cavity with Q=5 × 104. For comparison, the fractional frequency instability of a hydrogen maser is ∼10−13τ−1/2 at room temperature35 or ∼10−15τ−1/2 at cryogenic temperature36, and the state-of-the-art ytterbium atomic clock37 has a fractional frequency instability of ∼10−16τ−1/2. The optimal pump condition for a long coherence time can be obtained from equation (6). In the good-cavity or large ensemble limit where and at room temperature where nincoh≈nth, the optimal pump rate for maximum coherence time is close to that for maximum spin–spin correlation, that is, , and the optimal coherence time reaches , which scales with the spin number and the cavity Q-factor according to (see Supplementary Note 3). Note that the quantum coherence sustained by active masing (with a pump) has a much longer lifetime than the spin coherence protected by passive coupling to the cavity (without a pump)18. This is due to the superradiant emission of photons from the spin collective modes of the NV centres in the bulk diamond and the concomitant large number of photons in the cavity.
Diamond microwave amplifier
The coupled spin–cavity system can be configured as a room-temperature microwave amplifier when the spin population is inverted (Sz>0) but when the cavity Q-factor is below the masing threshold (Q<QC). For the readily accessible parameter Q=104, the noise temperature is as low as ∼0.2 K (versus ∼1 K for the state-of-the-art ruby amplifier working at liquid-helium temperature3). To study the amplification, we calculate the spin inversion, the microwave output power gain and the noise temperature with a weak microwave resonant input (see Methods and Supplementary Note 5). As shown in Fig. 3, the system linearly amplifies the microwave signal. The gain is about 6–10 dB under a 6–10-W pump with noise temperature 340–280 mK. At high pump around 136 W (w=104 s−1), the gain is as high as 20 dB with noise temperature as low as 200 mK. The low noise temperatures indicate the single-photon noise level.
Discussion
The ultralong coherence time of the maser is useful for metrology. The collective excitation of a large number of spins (∼1014) and cavity photons enhances the sensitivity. The sensitivity to a slow-varying magnetic field noise (with frequency ≤κS/2) for measurement time τ (see Supplementary Note 6), where γNV/2π=2.8 MHz G−1 is the NV centre gyromagnetic ratio. The magnetic field sensitivity is estimated to be in the order of 10–1 pT Hz−1/2 at room temperature (Tables 1 and 2). The temperature noise would induce cavity frequency fluctuation via thermal expansion and dielectric constant variation. The temperature sensitivity, (see Supplementary Note 6), is estimated to be in the order of 100–10 nK Hz−1/2 at room temperature (Tables 1 and 2), where we have taken g0≈(α+β/2)ωc=165 kHz K−1 with α and β being the temperature coefficients of thermal expansion and permittivity for sapphire, respectively (see Supplementary Note 1). For a higher cavity Q-factor, the thermometry sensitivity is enhanced while the magnetometry sensitivity is reduced (see Fig. 2e,f) due to the frequency dragging effect (the steady-state masing frequency is a weighted average of the spin and cavity frequency38, ω=(κcωS+κSωc)/(κc+κS), see Supplementary Note 2). The sensitivities to the magnetic field and the temperature noises set the requirements on stability of the set-up for maintaining the long coherence time of the maser.
The pump power is proportional to the pump light frequency (ωp), the pump rate (w) and the area of the pump light spot (S) divided by the NV centre absorption cross-section (σ) (see Supplementary Note 1). The threshold pump power is low because the spin relaxation time is long in diamond. For a readily accessible cavity with Q=5 × 104, we show diamond maser performance in Tables 1 and 2. The threshold pump power for microwave amplifying (population inversion) is estimated to be 2.7 W, above which the net photon emission into the cavity amplifies the signal. The threshold pump power for masing is estimated to be 4.3 W for Q=5 × 104 cavity (see Supplementary Note 1 for pump thresholds), above which the emitted photons show collective coherence and the photon number scales with the spin number (N) by nc∝N2.
The optical pump may heat the system, inducing both temperature increase and fluctuation. The frequency shifts of the spins and the cavity due to temperature increase are not an issue since once the steady-state is reached, the spin transition frequency can be tuned to resonance with the cavity mode by tuning the magnetic field.
It has been demonstrated that NV centre spins still have good coherence properties at least up to 600 K (ref. 19). According to ref. 19, the spin polarization, the pump rate and the decoherence time are only slightly changed at a temperature as high as 650 K. The longitudinal spin relaxation time T1 is reduced to 0.34 ms at 600 K, more than 10 times shorter than that at room temperature, and the pump threshold for microwave amplifying (w>1/T1) is fulfilled when the pump power is >40 W. Also, the contribution of the longitudinal spin relaxation to spin collective mode decay is negligible .
The temperature fluctuation leads to transition frequency shifts of the spins (via lattice expansion) and the cavity mode (via dielectric constant variation and mode volume expansion), with (2π)−1ΔωS/ΔT≈−74 kHz K−1 (ref. 39) and (2π)−1Δωc/ΔT≈−165 kHz K−1 (ref. 40) (see Supplementary Note 1). The masing conditions considered in this paper correspond to the photon leakage rate being much slower than the decay rate of the spin collective mode . Thus, the effects of temperature fluctuation on the maser result mainly from the cavity mode frequency fluctuation. Figure 4 shows the spin polarization, the output power, the masing linewidth and the coherence time as functions of the temperature fluctuation ΔT for cavity Q=5 × 104, and various pump rates (w=103, 104, 105 s−1). Note that the threshold cavity Q-factor is the lowest near w=104 s−1 (Fig. 2), thus the rate near w=104 s−1 is the most robust to temperature fluctuation. The masing condition is still fulfilled for up to 1.0 K temperature fluctuation at w=104 s−1. However, temperature fluctuation does affect the maser performance. In Table 1 (2), we compare the maser performance with and without the 0.2 K (0.5 K) temperature fluctuation for Q=5 × 104 cavity at low (high) pump power. For a larger number of spins, a larger temperature fluctuation can be tolerated (ΔTmax∝N) due to the reduced threshold cavity Q-factor.
Methods
Maser equations
The theoretical study is based on the standard Langevin equations33
where is the noise operator that causes the decay of the photons (c), the spin collective modes (S), the population in the excited state (e) or that in the ground state (g). Note that the total spin number is written as an operator to take into account the fluctuation due to the population of the third spin state and other intermediate states. The population fluctuation, however, has no effect on the phase fluctuation of the maser (see Supplementary Note 4).
By replacing the operators with their expectation values, we obtain the mean-field equations for the maser at the steady state
from which the masing frequency, the field amplitudes and the spin polarization can be straightforwardly calculated.
The coherence time and the linewidth are calculated using the spectrum of the phase fluctuations. The Langevin equations are linearized for the fluctuations, which are much smaller than the expectation values at steady state. The linearized equations are
By Fourier transform of these equations, the spectrum of the phase noise can be calculated and hence the maser coherence time and linewidth are determined.
To investigate the correlations in both the masing and the incoherent emission regimes, we derive the equations for the correlation functions and take the expectation values of the relevant operators. That leads to
Here, to make the equations close, we have used the approximation , and , neglecting the higher-order correlations, which is well justified for Gaussian fluctuations.
Microwave amplifier and noise temperature
To investigate the microwave amplifier, we solve the mean-field equations with a steady-state input as
from which the power gain is obtained. A power gain is possible under the resonant condition ωin=ωc=ωS, but it will be reduced to O(1) at off-resonance, that is, ≳1. The intrinsic noise temperature7 of the diamond maser is given by
where is the Planck constant, kB is the Boltzmann constant, T is the environment temperature, GdB=10log10 G and is the cavity power loss in decibel during the time of a microwave photon roundtrip time (ɛr≈10 is the sapphire dielectric permittivity in the direction perpendicular to the c axis (resonator axis) of the sapphire crystal, R is the radius of the cylindrical cavity and r (r0) is the external (internal) radius of the dielectric resonator).
Additional information
How to cite this article: Jin, L. et al. Proposal for a room-temperature diamond maser. Nat. Commun. 6:8251 doi: 10.1038/ncomms9251 (2015).
References
Gordon, J. P., Zeiger, H. J. & Townes, C. H. The maser—new type of microwave amplifier, frequency standard, and spectrometer. Phys. Rev. 99, 1264–1274 (1955) .
Elitzur, M. Astronomical masers. Annu. Rev. Astron. Astrophys. 30, 75–112 (1992) .
Clauss, R. C. & Shell, J. S. Ruby masers. In Low-Noise Systems in the Deep Space Network ed. Reid M. S. Deep Space Communication and Navigation Series, Jet Propulsion Laboratory (2008) .
Mollier, J. C., Hardin, J. & Uebersfeld, J. Theoretical and experimental sensitivities of ESR spectrometers using maser techniques. Rev. Sci. Instrum. 44, 1763–1771 (1973) .
Benmessai, K. et al. Measurement of the fundamental thermal noise limit in a cryogenic sapphire frequency standard using bimodal maser oscillations. Phys. Rev. Lett. 100, 233901 (2008) .
Kleppner, D. et al. Hydrogen-maser principles and techniques. Phys. Rev. 138, A972–A983 (1965) .
Siegman, A. E. Microwave Solid-State Masers McGraw-Hill (1964) .
Tsymbal E. Y., Žutić I. (eds) Hand Book of Spin Transport and Magnetism CRC (2011) .
Oxborrow, M., Breeze, J. D. & Alford, N. M. Room-temperature solid-state maser. Nature 488, 353–356 (2012) .
Kraus, H. et al. Room-temperature quantum microwave emitters based on spin defects in silicon carbide. Nat. Phys. 10, 157–162 (2014) .
Widmann, M. et al. Coherent control of single spins in silicon carbide at room temperature. Nat. Mater. 14, 164–168 (2015) .
Doherty, M. W. et al. The nitrogen-vacancy colour centre in diamond. Phys. Rep. 528, 1–45 (2013) .
Maze, J. R. et al. Nanoscale magnetic sensing with an individual electronic spin in diamond. Nature 455, 644–647 (2008) .
Balasubramanian, G. et al. Nanoscale imaging magnetometry with diamond spins under ambient conditions. Nature 455, 648–651 (2008) .
Acosta, V. M. et al. Diamonds with a high density of nitrogen-vacancy centers for magnetometry applications. Phys. Rev. B 80, 115202 (2009) .
Kubo, Y. et al. Hybrid quantum circuit with a superconducting qubit coupled to a spin ensemble. Phys. Rev. Lett. 107, 220501 (2011) .
Grezes, C. et al. Multimode storage and retrieval of microwave fields in a spin ensemble. Phys. Rev. X 4, 021049 (2014) .
Putz, S. et al. Protecting a spin ensemble against decoherence in the strong-coupling regime of cavity QED. Nat. Phys. 10, 720–724 (2014) .
Toyli, D. M. et al. Measurement and control of single nitrogen-vacancy center spins above 600 K. Phys. Rev. X 2, 031001 (2012) .
Redman, D. A., Brown, S., Sands, R. H. & Rand, S. C. Spin dynamics and electronic states of N-V centers in diamond by EPR and four-wave-mixing spectroscopy. Phys. Rev. Lett. 67, 3420–3423 (1991) .
Takahashi, S., Hanson, R., van Tol, J., Sherwin, M. S. & Awschalom, D. D. Quenching spin decoherence in diamond through spin bath polarization. Phys. Rev. Lett. 101, 047601 (2008) .
Jarmola, A., Acosta, V. M., Jensen, K., Chemerisov, S. & Budker, D. Temperature- and magnetic-field-dependent longitudinal spin relaxation in nitrogen-vacancy ensembles in diamond. Phys. Rev. Lett. 108, 197601 (2012) .
Harrison, J., Sellars, M. J. & Manson, N. B. Optical spin polarization of the N-V centre in diamond. J. Lumin. 107, 245–248 (2004) .
Manson, N. B., Harrison, J. P. & Sellars, M. J. Nitrogen-vacancy center in diamond: model of the electronic structure and associated dynamics. Phys. Rev. B 74, 104303 (2006) .
Robledo, L., Bernien, H., van der Sar, T. & Hanson, R. Spin dynamics in the optical cycle of single nitrogen-vacancy centres in diamond. N. J. Phys. 13, 025013 (2011) .
Tetienne, J. P. et al. Magnetic-field-dependent photodynamics of single NV defects in diamond: an application to qualitative all-optical magnetic imaging. N. J. Phys. 14, 103033 (2012) .
Neu, E. et al. Electronic transitions of single silicon vacancy centers in the near-infrared spectral region. Phys. Rev. B 85, 245207 (2012) .
Raich, H. & Blümler, P. Design and construction of a dipolar Halbach array with a homogeneous field from identical bar magnets: NMR Mandhalas. Concepts Magn. Reson. Part B Magn. Reson. Eng. 23B, 16–25 (2004) .
Anferova, S. et al. A mobile NMR device for measurements of porosity and pore size distributions of drilled core samples. Concepts Magn. Reson. Part B Magn. Reson. Eng. 23B, 26–32 (2004) .
Doğan, N., Topkaya, R., Subaşi, H., Yerli, Y. & Rameev, B. Development of Halbach magnet for portable NMR device. J. Phys. Conf. Ser. 153, 012047 (2009) .
le Floch, J.-M. et al. Dielectric material characterization techniques and designs of high-Q resonators for applications from micro to millimeter-waves frequencies applicable at room and cryogenic temperatures. Rev. Sci. Instrum. 85, 031301 (2014) .
Zhang, X., Zou, C.-L., Jiang, L. & Tang, H. X. Strongly coupled magnons and cavity microwave photons. Phys. Rev. Lett. 113, 156401 (2014) .
Kolobov, M. I., Davidovich, L., Giacobino, E. & Fabre, C. Role of pumping statistics and dynamics of atomic polarization in quantum fluctuations of laser sources. Phys. Rev. A 47, 1431–1446 (1993) .
Probst, S. et al. Three-dimensional cavity quantum electrodynamics with a rare-earth spin ensemble. Phys. Rev. B 90, 100404R (2014) .
Major, F. G. The Quantum Beat: Principles and Applications of Atomic Clocks Springer (2007) .
Vessot, R. F. C. The atomic hydrogen maser oscillator. Metrologia 42, S80–S89 (2005) .
Hinkley, N. et al. An atomic clock with 10–18 instability. Science 341, 1215–1218 (2013) .
Bohnet, J. G. et al. A steady-state superradiant laser with less than one intracavity photon. Nature 484, 78–81 (2012) .
Acosta, V. M. et al. Temperature dependence of the nitrogen-vacancy magnetic resonance in diamond. Phys. Rev. Lett. 104, 070801 (2010) .
Dobrovinskaya, E. R., Lytvynov, L. A. & Pishchik, V. Sapphire: Material, Manufacturing, Applications Springer (2009) .
Acknowledgements
This work was supported by the Hong Kong Research Grants Council Project No. 14303014 and The Chinese University of Hong Kong Vice Chancellor’s One-off Discretionary Fund.
Author information
Authors and Affiliations
Contributions
R.-B.L. conceived the idea and supervised the project. R.-B.L. and L.J. formulated the theory. R.-B.L., L.J., P.N., M.P., N.A., S.Y. and J.W. designed the physical system. L.J. carried out the calculations. R.-B.L. and L.J. wrote the paper. All authors commented on the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Supplementary Information
Supplementary Figures 1-2, Supplementary Note 1-6 and Supplementary References. (PDF 713 kb)
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Jin, L., Pfender, M., Aslam, N. et al. Proposal for a room-temperature diamond maser. Nat Commun 6, 8251 (2015). https://doi.org/10.1038/ncomms9251
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/ncomms9251
This article is cited by
-
Maser threshold characterization by resonator Q-factor tuning
Communications Physics (2023)
-
Review of noble-gas spin amplification via the spin-exchange collisions
Science China Information Sciences (2022)
-
A superradiant maser with nitrogen-vacancy center spins
Science China Physics, Mechanics & Astronomy (2022)
-
Nitrogen-vacancy centers promote super-radiant maser performance
Science China Materials (2022)
-
Universal lasing condition
Scientific Reports (2021)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.