Abstract
Quantum sensors have attracted broad interest in the quest towards sub-micronscale NMR spectroscopy. Such sensors predominantly operate at low magnetic fields. Instead, however, for high resolution spectroscopy, the high-field regime is naturally advantageous because it allows high absolute chemical shift discrimination. Here we demonstrate a high-field spin magnetometer constructed from an ensemble of hyperpolarized 13C nuclear spins in diamond. They are initialized by Nitrogen Vacancy (NV) centers and protected along a transverse Bloch sphere axis for minute-long periods. When exposed to a time-varying (AC) magnetic field, they undergo secondary precessions that carry an imprint of its frequency and amplitude. For quantum sensing at 7T, we demonstrate detection bandwidth up to 7 kHz, a spectral resolution < 100mHz, and single-shot sensitivity of 410pT\(/\sqrt{{{{{{{{\rm{Hz}}}}}}}}}\). This work anticipates opportunities for microscale NMR chemical sensors constructed from hyperpolarized nanodiamonds and suggests applications of dynamic nuclear polarization (DNP) in quantum sensing.
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Introduction
The discrimination of chemical analytes with sub-micron scale spatial resolution is an important frontier in nuclear magnetic resonance (NMR) spectroscopy1,2,3. Quantum sensing methods have attracted attention as a pathway to accomplish these goals4. These are typified by sensors constructed from the nitrogen vacancy (NV) defect center in diamond5,6—electrons that can be optically initialized and interrogated7,8, and made to report on nuclear spins in their environment. However, NV sensors are still primarily restricted to bulk crystals and operation at low magnetic fields (B0 < 0.3 T)9,10,11,12. Instead, for applications in NMR, high fields are naturally advantageous because the chemical shift dispersion is larger, and analyte nuclei carry higher polarization13. The challenge of accessing this regime arises from the rapidly scaling electronic gyromagnetic ratio γe, which makes electronic control difficult at high fields14,15. Simultaneously, precise field alignment16 is required to obtain viable NV spin-readout contrast17. The latter has also made nanodiamond (particulate) magnetometers challenging at high fields. If viable, such sensors could yield avenues for "targetable” NMR detectors that are sensitive to analyte chemical shifts18,19,20, and provide a sub-micron scale spatial resolution determined by particle size2,12,21. They also anticipate new applications in high-resolution high-field magnetometry in condensed matter systems22,23,24,25,26,27. In this paper, we propose alternate approach towards overcoming these technical challenges. We construct a magnetometer out of hyperpolarized nuclear spins (See Fig. 1): 13C nuclei in the diamond serve as the primary magnetic field sensors, while NV centers instead play a supporting role in optically initializing them28,29. By combining hyperpolarization, long-lived transverse sensor lifetimes, and their continuous interrogation, we show that nuclear magnetometers can produce sensitivities comparable to traditional electronic (NV center) sensors, but in the high-field regime.
The advantages of 13C nuclei as sensors stem from their attractive properties. Their low γn ≈ γe/3000, enables control and interrogation at high fields (B0 > 1 T). The benign scaling of the 13C Larmor frequency allows the scaling to higher magnetic fields to be easier than for NV centers. In contrast to NV electronic spins, transitions of spin-1/2 13C nuclei are determined solely by magnetic fields and not influenced by crystal lattice orientation29,30, so they need not be aligned in a specific direction. They have long rotating frame lifetimes \({T}_{2}^{\prime} \sim 90\) s 31, orders of magnitude greater than their NV center counterparts. Similarly, their longitudinal lifetimes T1 > 10 min32,33 are long even at modest fields. This can allow a physical separation between field regions corresponding to 13C initialization and sensing, and for the 13C sensors to be transported between them33. 13C nuclei can be non-destructively readout via RF techniques34, allowing continuous sensor interrogation without reinitialization. This allows real-time tracking of a changing magnetic field for extended periods35. RF 13C readout is also background-free, i.e., the 13C signal from the hyperpolarized diamond is likely orders of magnitude stronger than the surrounding analyte36. Moreover, it is immune to optical scattering37, permitting deployment in real-world media.
While these properties appear attractive at first glance, nuclear spins have previously been considered ineffective as quantum sensors. The low γn, while ideal for high field operation, would be expected to yield low sensitivity4, and poor state purity (thermal polarization is ≈ 10−5 even at 7 T). Strong ( ~ 1 kHz) dipolar coupling between 13C nuclei makes Ramsey-like sensing protocols untenable. This results in a rapid free induction decay (FID) \({T}_{2}^{*} < \)2 ms34 and limits sensor integration time.
Here, we demonstrate that these shortcomings can be mitigated. We exploit optical hyperpolarization of 13C nuclei (Fig. 1A)28,29,38,39 and spin-lock readout scheme that suppresses evolution under dipolar interactions31,40. The resulting > 10,000-fold extension in 13C lifetimes, from \({T}_{2}^{*}\to {T}_{2}^{\prime}\), provides the basis for expanding sensor readout to minute long periods31. These long 13C rotating-frame lifetimes can at least partially offset sensitivity losses arising from the low γn. The sensing strategy is described in Fig. 1B. Hyperpolarized 13C nuclei are placed along the transverse axis \(\hat{{{{{{{{\bf{x}}}}}}}}}\) (red arrow) on the Bloch sphere at high field, where they are preserved for multiple-second long \({T}_{2}^{\prime}\) periods31. Any subsequent deviation of the spin state from \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane can be continuously monitored and constitutes the magnetometer signal. In the presence of the target magnetic field, \({{{{{{{{\bf{B}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}(t)={B}_{{{{{{{{\rm{AC}}}}}}}}}\cos (2\pi {f}_{{{{{{{{\rm{AC}}}}}}}}}t+{\varphi }_{0})\hat{{{{{{{{\bf{z}}}}}}}}}\) at a frequency fAC, the nuclei undergo a secondary precession in the \(\hat{{{{{{{{\bf{y}}}}}}}}}-\hat{{{{{{{{\bf{z}}}}}}}}}\) plane that carries an imprint of fAC. Long \({T}_{2}^{\prime}\) yields high spectral resolution.
As opposed to traditional quantum sensing, magnetometry is performed here with nuclear spins already in "coupled-sensor” limit, i.e., in the regime where \(\left\langle d\right\rangle {T}_{2}^{*} \sim 1\). The key novelty of our approach is (1) the ability to mitigate this intersensor coupling while simultaneously (2) rendering spins sensitive to external magnetic fields. The protocol we propose achieves these twin aims in a highly robust manner evidenced by the ability to apply > 250,000 pulses to the sensor spins while continuously tracking their evolution. Moreover, unlike conventional quantum sensing, here by measuring amplitude and phase of the sensor response, we are able to discern the sensor position on two quadratures simultaneously on the Bloch sphere.
Results
High-field magnetometry with hyperpolarized 13C nuclei
Experiments here are conducted on a single-crystal diamond, but can be extended to powders. The sample has ~ 1 ppm NV center concentration and natural abundance 13C. Hyperpolarization occurs through a method previously described at 38 mT29,36 (see Supplementary Note 6 for a summary of the method and setup). Figure 2 shows the subsequently applied 13C magnetometry protocol at 7 T. It entails a train of θ pulses, spin-locking the nuclear spins along \(\hat{{{{{{{{\bf{x}}}}}}}}}\) (Fig. 2A). 13C nuclei remain in quasi-equilibrium along \(\hat{{{{{{{{\bf{x}}}}}}}}}\) for several seconds31. Flip angle θ can be arbitrarily chosen, except for θ = π34. Pulse duty cycle is high (19–54%) and interpulse spacing τ < 100 μs (Fig. 2A). The nuclei are inductively interrogated in tacq windows between pulses. Orange curves in Fig. 2B show typical raw data. For each window, the magnitude of the heterodyned Larmor precession, (Fig. 2C, here at 20 MHz)—effectively the rotating frame transverse magnetization component—constitutes the magnetometer signal. These are the blue points in Fig. 2D. Every pulse, therefore, provides one such point; in typical experiments we apply N ≳ 200k pulses. In the absence of an external field, successive points show very little decay. We typically achieve transverse spin lifetimes exceeding >30 s; remarkably however, this is accomplished using a pulsing rate that is only a factor of 10-fold faster than the interspin dipolar coupling. Now, when subject to an AC field at fAC, there is an oscillatory response (evident in blue line Fig. 2D). It is strongest at the "resonance condition”,
as will be explained below, corresponding to when the AC field periodicity is matched to the time to complete a 2π rotation. Figure 2A describes the resonant situation for θ ≈ π/2.
Figure 3 shows the magnetometer signal over 20 s (275k pulses) with no applied field and fAC = 2.760 kHz (close to resonance). In the former case, there is a slow decay \({T}_{2}^{\prime}=31\) s (red line in Fig. 3A)31. The AC field however drives the spins away from \(\hat{{{{{{{{\bf{x}}}}}}}}}\), causing a comparatively rapid 13C decay (blue line in Fig. 3A) along with magnetization oscillations (see Fig. 3C). We separate these contributions, decomposing the signal (dashed box) as S = Sd + So, where Sd is the (slow) decay component (Fig. 3B) and So is the oscillatory part with zero mean (Fig. 3C, zoomed in Fig. 3D). In practice, Sd is obtained via a 73 ms moving average filter applied to S in Fig. 2, and the oscillatory component isolated as So = S − Sd.
We first focus attention to the decay component Sd. In Fig. 4, we vary fAC, and study the change in integrated value of Sd over a 5 s period (Fig. 3B). Here the phase of the applied AC field is random. Figure 4A reveals that the 13C decay is unaffected for a wide range of frequencies, except for a sharp decay response (dip) centered at resonance \({f}_{{{{{{{{\rm{res}}}}}}}}}\) (dashed vertical line). With a Gaussian fit, we estimate a linewidth ≈ 223 Hz. The dip matches intuition developed from average Hamiltonian theory (AHT) (Fig. 4B, C) (see below). It can be considered to be an extension of dynamical decoupling (DD) sensing41,42 for arbitrary θ. Figure 4D shows the scaling of \({f}_{{{{{{{{\rm{res}}}}}}}}}\) with pulse width tp. This agrees well with theoretical scaling, \({f}_{{{{{{{{\rm{res}}}}}}}}}=A{t}_{p}/({t}_{p}+{t}_{{{{{{{{\rm{dead}}}}}}}}}+{t}_{{{{{{{{\rm{acq}}}}}}}}})\), where A is a measure of the Rabi frequency.
Figure 4E, F, display individual decays in Fig. 4A on a linear scale and logarithmic scale against \(\sqrt{t}\). Points far from resonance (e.g., (i) DC and (iv) 5 kHz) exhibit a stretched exponential decay \(\propto \exp (-{t}^{1/2})\), characteristic of interactions with the P1 center spin bath31. These manifest as the straight lines in Fig. 4F. On the other hand, for points within the \({f}_{{{{{{{{\rm{res}}}}}}}}}\) dip in Fig. 4A, we observe a potentially chaotic response evidenced by sharp jumps (Fig. 4E, F). These features belie a simple explanation from AHT alone and is possibly an artifact from our probe like arcing. The jumps occur for strong Rabi frequencies, and when fAC approaches resonance, evident in the comparison between fAC = 5kHz and fAC = 2.885 kHz in Fig. 4E, F (blue and yellow lines). Figure 4G describes the linewidth dependence of the obtained resonance dip as a function of the number of pulses employed. Contrary to DD sensing10,43,44,45, the linewidth does not fall with increasing number of pulses, suggesting it is dominated by 13C dipolar couplings.
Despite this relatively broad linewidth, high resolution magnetometry can be extracted from the oscillatory component So (Fig. 3C). Figure 5A shows So over 20 s for fAC = 2.760 kHz. Figure 5B zooms into a representative 22 ms window. Strong 13C oscillations are evident here. Taking a Fourier transform, we observe four sharp peaks (Fig. 5C). We identify the two strongest peaks as being exactly at fAC and 2fAC (shown in Fig. 5C with the labels ① and ②); we will refer to them as primary and secondary harmonics respectively. They are zoomed for clarity in Fig. 5D, E (along with the noise level in Fig. 5F), from which we extract the AC magnetometry linewidths as 92 mHz and 96 mHz respectively. Two other smaller peaks in Fig. 5C are aliased versions of the third and fourth harmonics (marked ③ − ④), at frequencies \({f}_{3}=2{{{{{{{\mathcal{B}}}}}}}}-3{f}_{{{{{{{{\rm{AC}}}}}}}}}=5.418\) kHz and \({f}_{4}=2{{{{{{{\mathcal{B}}}}}}}}-4{f}_{{{{{{{{\rm{AC}}}}}}}}}=2.658\) kHz. The bandwidth \({{{{{{{\mathcal{B}}}}}}}}=1/(2\tau )\) here is determined by the interpulse interval in Fig. 2A. For clarity, Fig. 5G shows the data in Fig. 5C in a logarithmic scale, with the harmonics marked.
We emphasize differences with respect to DD quantum sensing10,11. Oscillations here are at the absolute AC frequency fAC, as opposed to the difference frequency from τ−1 in the DD case. Second, sensing can be obtained with an arbitrary flip angle θ (except π), allowing for greater robustness compared to DD sequences that require precisely calibrated θ = π pulses. Pulse error affects AC magnetometry peak intensity but not their position. Figure 5H shows the scaling of the harmonic intensities with ∣BAC∣. We observe a linear and quadratic dependence of the primary and secondary harmonic intensities (see Fig. 5H), differing from DD sensing.
We now perform experiments to determine the frequency response of the sensor, unraveling the sensitivity profile at different frequencies (Fig. 6). We seek to determine how it relates to the \({f}_{{{{{{{{\rm{res}}}}}}}}}\) dip in Fig. 4. We apply a chirped AC field, \({f}_{{{{{{{{\rm{AC}}}}}}}}}(t)={f}_{{{{{{{{\rm{ini}}}}}}}}}+(\Delta {{{{{{{\mathcal{B}}}}}}}}/T)t\), with fini = 1 kHz, in a 1–4 kHz window (\(\Delta {{{{{{{\mathcal{B}}}}}}}}=3\)kHz) in Fig. 6A (shaded region. The sweep is slow, (T = 20 s), and occurs only once during the full sequence, and does not start synchronously with it. If the frequency response was independent of frequency, we would expect an approximately box-like Fourier signal intensity over \(\Delta {{{{{{{\mathcal{B}}}}}}}}\). Instead, we obtain a narrow response with a central cusp in a small portion of the \(\Delta {{{{{{{\mathcal{B}}}}}}}}\) band (zoomed in Fig. 6B). This response is strongest close to resonance (Eq. (1)), a signature of the sign inversion of the 13C spins due to the rapid adiabatic passage driven by the AC field in the rotating frame. Upon hitting the resonance condition, the spins tip towards the \(\hat{{{{{{{{\bf{y}}}}}}}}}-\hat{{{{{{{{\bf{z}}}}}}}}}\) plane and their amplitude in the \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane, as measured, reduces. Simultaneously, we observe a strong Gaussian response in the region outside \(\Delta {{{{{{{\mathcal{B}}}}}}}}\) (Fig. 6C). We identify these features as the primary and secondary harmonic responses, respectively (labeled ① and ② as before). Indeed, their frequency centroids are in the ratio 1:2 (see Fig. 5C); \({f}_{{{{{{{{\rm{res}}}}}}}}}\) arises where the cusp dips to its lowest point (dashed line in Fig. 6B). We hypothesize that the cusp arises because the actual signal response reflects a dispersive lineshape, flipping in sign on either side of resonance \({f}_{{{{{{{{\rm{res}}}}}}}}}\) (see Sec. II B).
Figure 6 suggests the potential for real-time magnetic field "tracking”. We consider this experimentally in Fig. 7. Figure 7A shows So corresponding to a single-shot of the experiment in Fig. 6A. Sensor response is enhanced as the frequency crosses resonance \({f}_{{{{{{{{\rm{res}}}}}}}}}\) (dashed line). Three 15 ms windows are displayed in Fig. 7B. Their Fourier transforms reveal that the frequency response follows the instantaneous AC field fAC(t).
Theory
We now turn to a theoretical description of 13C sensor operation. We outline two complementary viewpoints to explain the observations in Figs. 4 and 5: a first picture equivalent to DD quantum sensing, and second using an "rotating-frame” NMR experiment analogue. Consider first that the 13C Hamiltonian in the lab-frame is, \({{{{{{{\mathcal{H}}}}}}}}={{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{Z}}}}}}}}}+{{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{dd}}}}}}}}}+{{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}\), where \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{Z}}}}}}}}}={w}_{{{{{{{{\rm{L}}}}}}}}}{I}_{z}\) is the Zeeman Hamiltonian, \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{dd}}}}}}}}}={\sum }_{k\,{ < }\,\ell }{b}_{k\ell }(3{I}_{kz}{I}_{\ell z}-\overrightarrow{{I}_{k}}\cdot \overrightarrow{{I}_{\ell }})\) is the interspin dipolar interaction and \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}={\gamma }_{n}{B}_{{{{{{{{\rm{AC}}}}}}}}}\cos (2\pi {f}_{{{{{{{{\rm{AC}}}}}}}}}t+{\varphi }_{0}){I}_{z}\) is the applied AC field. Here I refer to spin-1/2 Pauli matrices, wL is the nuclear Larmor frequency, φ0 is the initial (arbitrary) phase of the AC field, and we estimate the median dipolar coupling \(J=\left\langle {b}_{k\ell }\right\rangle \, \approx\) 663Hz. The spins are prepared initially along \(\hat{{{{{{{{\bf{x}}}}}}}}}\) in a state ρ(0) ~ εIx, where ε ≈ 0.2% is the hyperpolarization level.
The sequence in Fig. 2A can be conveniently treated in the rotating frame by average Hamiltonian theory (AHT)46. After N pulses, its action can be described by the unitary, \(U(N\tau )={\left[\exp (i\theta {I}_{x})\exp (i{{{{{{{\mathcal{H}}}}}}}}\tau )\right]}^{N}\), where we assume δ-pulses for simplicity. The signal obtained following the procedure in Fig. 2 then simply corresponds to the measurement of \({[{\langle {I}_{x}\rangle }^{2}+{\langle {I}_{y}\rangle }^{2}]}^{1/2}\), or equivalently the spin survival probability in the \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane. This evolution can be expressed as, \(U(N\tau )=\mathop{\prod }\nolimits_{j=1}^{N}\exp (i{{{{{{{{\mathcal{H}}}}}}}}}^{(\,\,j)}\tau )\), where \({{{{{{{{\mathcal{H}}}}}}}}}^{(j)}\) are toggling frame Hamiltonians after every pulse46, \({{{{{{{{\mathcal{H}}}}}}}}}^{(j)}=\exp (ij\theta {I}_{x}){{{{{{{\mathcal{H}}}}}}}}\exp (-ij\theta {I}_{x})\). For time t = Nτ, this can be recast as, \(U(t)=\exp (i{{{{{{{{\mathcal{H}}}}}}}}}_{F}N\tau )\), where \({{{{{{{{\mathcal{H}}}}}}}}}_{F}\) captures the effective system dynamics under the pulses. To leading order in parameter ζ = 2πJτ in a Magnus expansion47,48,49, and assuming ζ ≪ 1, the dynamics can be captured by an average Hamiltonian, \({{{{{{{{\mathcal{H}}}}}}}}}_{F}^{(0)}=\mathop{\sum }\nolimits_{j=1}^{N}{{{{{{{{\mathcal{H}}}}}}}}}^{(j)}\).
Since non-commuting effects do not affect the leading order term, we can consider the effect of each of the dipolar part and the AC field separately, \({{{{{{{{\mathcal{H}}}}}}}}}_{F}^{(0)}={{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{dd}}}}}}}}}^{(0)}+{{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}^{(0)}\). For the former, we have34,
with the flip-flop Hamiltonian, \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{ff}}}}}}}}}={I}_{jz}{I}_{kz}+{I}_{jy}{I}_{ky}\). The initial state ρ(0) is conserved under \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{dd}}}}}}}}}^{(0)}\), since \([\rho (0),{{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{dd}}}}}}}}}^{(0)}]=0\). This leads to a quasi-equilibriation of spins along \(\hat{{{{{{{{\bf{x}}}}}}}}}\), with a lifetime that scales with a power law of the pulsing frequency τ−131. This is the red signal in Fig. 3A (here ζ = 0.3). We note that for sufficiently small ζ, Eq. (2) is valid for arbitrary flip-angle θ, except for certain special values (θ ≈ π, 2π).
A similar AHT analysis can be carried out for the \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}\) term. Consider first a DC field (fAC = 0) and θ = π/2. Figure 2C shows the toggling frame Hamiltonians \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}^{(\,\,j)}\), which consists only of single body terms and hence can be plotted in a phasor representation. In a cycle consisting of four pulses (required to complete a 2π rotation), the average Hamiltonian \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}^{(0)}=0\), evident from the symmetrically distributed phasors in Fig. 4(i). Hence the DC field is decoupled. Alternately, consider the resonant AC case (\({f}_{{{{{{{{\rm{AC}}}}}}}}}={f}_{{{{{{{{\rm{res}}}}}}}}}\)). The analysis here is simplest to carry out assuming a square-wave (as opposed to sinusoidal) field. In this situation, the phasor diagram is asymmetrical and the average Hamiltonian after four pulses, \({{{{{{{{\mathcal{H}}}}}}}}}_{{{{{{{{\rm{AC}}}}}}}}}^{(0)}\propto -{I}_{y}\). When stroboscopically observed, the spins rotate away from \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane; this yields the dip in the integrated signal in Fig. 4.
An illuminating alternate viewpoint is obtained by noting that under spin-locking the spins are requantized in the rotating frame with an effective field, \({\Omega }_{{{{{{{{\rm{eff}}}}}}}}}=\Omega \left(\frac{{t}_{p}}{\tau }\right)\), where the factor in brackets is the pulsing duty cycle, and Ω is the Rabi frequency. The resonance frequency identified above is then exactly, \({f}_{{{{{{{{\rm{res}}}}}}}}}={\Omega }_{{{{{{{{\rm{eff}}}}}}}}}\). Therefore the experiment can cast as an rotating-frame analogue of a conventional (lab-frame) NMR experiment: the spins are quantized along \(\hat{{{{{{{{\bf{x}}}}}}}}}\), Ωeff serves analogous to the Larmor frequency, and at the resonance condition (\({f}_{{{{{{{{\rm{AC}}}}}}}}}={f}_{{{{{{{{\rm{res}}}}}}}}}\)), BAC is the effective Rabi frequency. Spins initially prepared along \(\hat{{{{{{{{\bf{x}}}}}}}}}\), are then constantly tipped away from this axis by fAC. The dip in Fig. 4 reflects this tilt away from the \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane. For the resonant case, in the absence of dipolar evolution, the trajectory of the spins in the rotating frame can be simply written as,
In effect, the spins are undergoing a "secondary” precession in the rotating frame around \(\hat{{{{{{{{\bf{x}}}}}}}}}\) at frequency Ωeff. For each point on this motion, they are also precessing in the lab frame at wL. The latter yields the inductive signal measured in the raw data in Fig. 2B. Upon taking a Fourier transform (Fig. 2C), we are able to extract the magnitude of the spin vector in the \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane, which has the form, \(S(t)={[{\cos }^{2}({\gamma }_{n}{B}_{{{{{{{{\rm{AC}}}}}}}}}t)+{\sin }^{2}({\gamma }_{n}{B}_{{{{{{{{\rm{AC}}}}}}}}}t){\sin }^{2}(2\pi {f}_{{{{{{{{\rm{AC}}}}}}}}}t)]}^{1/2}\). This is the signal measured in Fig. 3, and the oscillations here at fAC and 2fAC, corresponding to the observed first and second harmonics respectively. While this analysis was for the resonant case, it is simple to extend it to off-resonant AC fields (see Supplementary Note 9). Once again the oscillations can be demonstrated to be at exact harmonics of fAC. Alternatively, if the FT phase, instead of magnitude (see Supplementary Note 5), was taken in Fig. 2C, where one measures the phase of the spins in the \(\hat{{{{{{{{\bf{x}}}}}}}}}-\hat{{{{{{{{\bf{y}}}}}}}}}\) plane in the rotating frame, Eq. (3) indicates there will once again be oscillations. Here however, all the intensity will be in the primary harmonic, and for sufficiently small fields γn∣BAC∣ ≪ fAC, the oscillatory signal scales ∝ ∣BAC∣, and can provide higher sensitivity. Extracting these oscillations comes with complications related to unwrapping the phase every 2π, and accounting for phase accrual during the tp pulse periods. Supplementary Note 5 elucidates the phase unwrapping strategy employed in this work.
Overall Eq. (3) illustrates that the oscillations in Fig. 5 are akin to observing the Larmor precession of the spins in the rotating frame. The growing oscillation strength in Fig. 5A might indicate the spins tipping further away from the \(\hat{{{{{{{{\bf{x}}}}}}}}}\) axis. In a similar manner, Eq. (3) demonstrates that Figs. 6 and 7 are analogous to the AC field driving a rapid adiabatic passage in the rotating frame. Therefore, the sign of \(\left\langle {I}_{x}\right\rangle\) flips on either side of the resonance (see Fig. 6).
Finally, we emphasize that the treatment above is still only qualitative because it neglects the effect of the dipolar interactions during the full spin-locking sequence. An interplay between the dipolar interaction and AC field is ultimately important in determining the transverse lifetimes upon spin excursions away from the \(\hat{{{{{{{{\bf{x}}}}}}}}}\) axis. We will consider this in detail in follow-up work.
13C sensor performance and special features
We now elucidate parameters of 13C sensor performance and discuss some of its special features (see SI (See supplementary online material) for a summary). Our emphasis in this paper was not to optimize sensitivity, but through experiments similar to Fig. 4 (detailed in Supplementary Note 11) for a bias field B0 = 7 T and at the resonance frequency, we obtain a single-shot sensitivity of 760 ± 127 pT\(/\sqrt{{{{{{{{\rm{Hz}}}}}}}}}\) via measurement of signal amplitude, and 410 ± 90 pT\(/\sqrt{{{{{{{{\rm{Hz}}}}}}}}}\) via measurement of signal phase respectively. This neglects hyperpolarization time because a sensor initialization event can allow interrogation for several minutes31. A single-shot of the measurement (for t = 34s at \({f}_{{{{{{{{\rm{res}}}}}}}}}\)) can detect a minimum field of ≈ 70 pT. While the sensitivity here is lower than NV quantum sensors at low field, we emphasize that this corresponds to an exquisite AC field precision of ~ 10−11 over the 7 T bias field. Indeed, as elucidated in Supplementary Note 13, our 13C sensor occupies a niche space of high-field operation with few competing technologies (MOKE, SHPM, and 1H NMR). While possessing comparable sensitivity, it expands applications to multiplexed sensing of AC fields that is not easily feasible via these sensor technologies.
Sensitivity itself can be significantly enhanced. Sample filling factor (presently η ≈ 15%) and RF coil Q-factor ( ≈ 30) can both be significantly boosted. Employing a 10% 13C enriched sample would provide a further ten-fold gain in inductive signal strength34. Current hyperpolarization levels are around ( ≈ 0.1%), but we anticipate that technical improvements can boost this by a further 50-fold50. Experiments in this paper have been conducted on a single crystal sample, but we anticipate similar long coherence times \({T}_{2}^{\prime}\) can be accomplished for nanodiamond (ND) samples via methods of high-temperature sample thermal annealing51. From these concerted gains, we estimate a sensitivity approaching 2 nT\(/\sqrt{\,{{\mbox{Hz}}}}\) is feasible for 13C-enabled NMR detection in a (10 μm)3 volume, sufficient to measure the ~ 11 nT field produced by precessing 1H nuclei of glycerol in the same volume at 10 T12.
The frequency resolution of the 13C sensor is δf ≈ 1/Nτ. Currently, Fig. 5 demonstrates a resolution ~ 50 mHz. However, finite memory limitations restricted capturing the 13C Larmor precession here to t < 35s (Fig. 5A). Overcoming these memory limits can allow acquisition of the entire spin-lock decay, lasting over 573 s31. Under these conditions, we estimate a frequency resolution of 2.2 mHz is feasible. This would correspond to a frequency precision of 3 ppt at a 7 T bias field. On the other hand, sensor bandwidth \({{{{{{{\mathcal{B}}}}}}}}=1/2\tau\) is determined by the minimum interpulse delay (see Fig. 4C). Current Rabi frequencies limit bandwidth to ~ 20 kHz. We estimate that improving filling-factor η and RF coil Q factor (presently 30), could increase \({{{{{{{\mathcal{B}}}}}}}}\) further to ≈ 500 kHz. The sensor strategy lends itself to a wide operating field range. While our experiments were carried out at 7 T, the slow scaling 13C gyromagnetic ratio makes sensing viable even for fields ≳ 24 T. This greatly expands the field range for spin sensors, where the operating field is predominantly < 0.3 T (notable exceptions are Refs. 13,15, but require complex instrumentation).
We emphasize the robustness of our sensing method to pulse error. It can be operated with any flip angle θ ≠ π34. Moreover, \({f}_{{{{{{{{\rm{res}}}}}}}}}\) has a relatively wide profile ≈ 230 Hz (see Fig. 4A), meaning that flip-angle (RF) inhomogeneity has little impact. These features are responsible for the > 275k pulses applied to the 13C spins in experiments in this work.
Finally, we note some special features of our magnetometry protocol. Compared to previous work52 using hyperpolarized gaseous 129Xe nuclei as sensors, our experiments employed hyperpolarized nuclear spins in solids. This provides natural advantages due to an ability for in-situ replenishment of hyperpolarization at the sensing site. Moreover, multiple AC fields can be discerned in a Fourier reconstruction in a single-shot, as opposed to point-by-point52.
Fundamentally, experiments here illustrate the feasibility of quantum sensing in the coupled sensor limit (\( < d > {T}_{2}^{*} \sim 1\))53,54, making the spins sensitive to external fields while negating the effect of intersensor interactions. Sensor operation exploits "Floquet prethermalization”55,56—quasi-equilibrium nuclear states under periodic driving31. As such, this provides a compelling demonstration of exploiting stable non-equilibrium phases for sensing applications.
From a technological perspective, RF interrogated sensing, as described here, presents advantages in scattering environments37 (see Supplementary Note 12). All data in this paper are carried out with the diamond immersed in ~ 4mL water, over 2000-fold the volume of the sample. Traditional NV sensors are ineffective in this regime due to scattering losses and concomitant fluorescence fluctuations. Similarly, optically hyperpolarized sensors present advantages because majority of the sensor volume can be illuminated by the impinging lasers, because there are no geometrical constraints from the requirements of collection optics. In our experiments, we employed an array of low-cost laser diode sources50 for hyperpolarization that illuminates the sample almost isotropically. This allows recruiting a larger volume of spins for sensing with a low cost overhead50. Extension to powder samples could be advantageous for optimally packing a sensor volume.
Discussion
The work presented here can be extended in several promising directions. First, the high bandwidth-to-resolution ratio (\({{{{{{{\mathcal{B}}}}}}}}/\delta f\,\approx\, 1{0}^{5}\)) possible via 13C sensing at high fields (see Fig. 5), suggests possibilities for detecting chemical shifts from processing analyte nuclei external to the diamond. Seminal work by Warren et al.57 and Bowtell58 showed that nuclear spins of one species ("sensor”) could be used to indirectly probe NMR information of other physically separated ("analyte”) nuclei. This indirect NMR detection strategy is appealing as the absolute dimensions diminish to sub-micron length scales2. Building on these ideas, we envision the possibility of micro-scale NMR detectors using hyperpolarized 13C nuclei in nanodiamond (ND) particles, and exposing one-half of the particle surfaces to the analyte57. Such "relayed" NMR detection is feasible because of the high resolution-to-bandwidth ratio of our 13C magnetometer ( < 10 ppm). For instance, the detection of 1H analyte chemical shifts would require the translation of the corresponding nuclear Larmor precession into the magnetometer detection bandwidth ( ~ 7 kHz)59,60. Such frequency translation is possible following the approach first introduced by Wittfield and Redfield61 of detecting oscillating longitudinal spin magnetization at audio-frequencies. In principle, this requires additional control applied to the analyte nuclei. For instance, a train of π/2 pulses applied to the 1H nuclei coincident with the spin-locking train applied to the 13C sensor nuclei in Fig. 2A allows 1H chemical shift information to be encoded into longitudinal 1H magnetization oscillations and hence still retained. Ultimately, the spatial distance over which the sensing extends will be determined approximately by the size of the 13C sensor ensemble employed12, hence opening the possibility of micron-scale NMR detection. We will explore these experiments in a future manuscript.
Second, while the current experiments exploit a low-field DNP mechanism for the initialization of the 13C sensors, interesting opportunities arise from employing complementary all-optical DNP techniques that operates directly at high field62,63. This will allow in-situ sensors at high field without the need for sample shuttling.
Furthermore, beyond NMR, we envision applications to condensed matter physics. Our approach might enable non-invasive and high spatial resolution visualization of the observed phenomenology of domain walls in 2D ferromagnets22,23, elucidation of coexisting antiferromagnetic and spin-glass phases in 2D crystals25, and reentrant Hofstadter phases in twisted bilayer graphene at high magnetic fields27.
More broadly, this work suggests an interesting applications of DNP for quantum sensing. It is intriguing to consider sensor platforms constructed in optically-active molecular systems64 where abundant, long-lived nuclear spins, can be initialized via interactions with electronic spin centers. Finally, we envision technological applications of the 13C sensors described here for bulk magnetometry65, sensors underwater and in scattering media, and for spin gyroscopes66,67,68,69.
In conclusion, we have proposed and demonstrated a high-field magnetometry approach with hyperpolarized 13C nuclear spins in diamond. Sensing leveraged long transverse spin 13C lifetimes and their ability to be continuously interrogated, while mitigating effects due to interspin interaction. We demonstrated magnetometry with high frequency resolution ( ~ 50 mHz), high field precision ( ~ 10−11), and high-field (7T) operation, yielding advantages over counterpart NV sensors in this regime. This work opens avenues for NMR sensors at high fields, and opens new and interesting possibilities for employing dynamic nuclear polarization for quantum sensing.
Methods
The diamond sample employed in this work is a single crystal CVD grown sample from Element6 with ~ 1ppm of NV centers. Initialization of the 13C nuclei via hyperpolarization is carried out via continuous laser illumination and chirped microwave excitation at low magnetic field (36–40 mT). The 13C magnetometry experiments here are all carried out at 7T. The spins are continuously interrogated in the windows between the θ-pulses, and digitized by means of a fast arbitrary waveform transceiver (Tabor Proteus). This allows us to measure the amplitude and phase of the 13C Larmor precession signal, from which we extract the transverse Bloch sphere components of the spin vector in the rotating frame. The AC field is applied by means of a \(\hat{{{{{{{{\bf{z}}}}}}}}}\)-coil parallel to the 13C quantization axis at 7T. More details about all these aspects, including instrumentation, protocols, and additional data are presented in the supplementary information.
Data availability
The data necessary to replicate the results of this paper are available from the corresponding author upon reasonable request.
Code availability
The code required to reproduce the graphs and analysis in this paper are available in this Berkeley Box file sharing repository: https://berkeley.box.com/s/41ntv00tg5htvtqged3boyli5tn04q47.
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Acknowledgements
We gratefully acknowledge M. Markham (Element6) for the diamond sample used in this work, and for discussions with J. Reimer, C. Meriles, D.Suter, and H. Oaks-Leaf. This work was funded by ONR under N00014-20-1-2806 (Roberto Diener). Support to B.G. was provided by U.S. DOE Office of Basic Energy Sciences, Chemical Sciences, Geosciences, and Biosciences Division under Contract DE-AC02-05CH11231.
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A.A. designed the project and supervised the experimental effort. O.S. performed all experiments. O.S. and A.A. performed the theoretical analysis and simulations. O.S. E.S., S.C., A.Ak., A.Ag. performed data analysis and contributed to data visualization. E.D. and P.R. constructed the experimental apparatus and NMR probe. B.G. and S.B. contributed materials. A.A., E.S., O.S., S.C. and A.Ak. wrote the paper with input from all authors.
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Sahin, O., de Leon Sanchez, E., Conti, S. et al. High field magnetometry with hyperpolarized nuclear spins. Nat Commun 13, 5486 (2022). https://doi.org/10.1038/s41467-022-32907-8
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DOI: https://doi.org/10.1038/s41467-022-32907-8
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