Introduction

Stabilized narrow-linewidth lasers, operating across a wide range of visible (VIS) to short-wave infrared (SWIR) wavelengths, are essential tools for applications such as neutral atom and trapped-ion based quantum sensing and computing1,2,3, ultra-low phase noise microwave and mmWave generation4,5,6,7, and fiber sensing8,9. These applications can benefit from the integration of today’s lab-scale stabilized lasers, leading to a reduction in size, cost, and power consumption and improvement in reliability and stability. Integrated solutions that can replace these lasers must meet the required low phase noise and carrier stability while at the same time support laser emission and reference cavity operation that by design can span over an octave wavelength range from the VIS to SWIR.

Today, precision systems are constructed using SWIR fiber lasers or external cavity diode lasers that are Pound Drever-Hall (PDH) locked to bulk-optic ultra-low expansion (ULE) reference cavities10,11,12,13,14. The table-top lasers reduce the mid- to high-frequency offset noise while the reference cavity is used to mitigate close-to-carrier noise and improve carrier stability. To accommodate VIS light applications, these solutions incorporate bulk-optic or waveguide second harmonic generation (SHG)15. Progress has been made on miniaturization of reference cavities using micro-optic designs16,17,18, yet such solutions are not amenable to photonic integration, do not support agile tuning for stabilization to atomic references, and have large GHz-scale free spectral range (FSR) that do not support locking of fine resolution wavelength tuning.

Integrated approaches can employ dual-stage laser noise reduction using a first stage integrated laser with nonlinear suppression of high-frequency offset noise, followed by a second cavity stage that reduces low- to mid-frequency offset noise19. Integrated lasers that employ non-linear feedback mechanisms include stimulated Brillouin scattering (SBS) and self-injection locking, and have been demonstrated in the VIS20,21,22,23,24 to SWIR25,26,27,28. Integrated stabilization cavities, such as coil or spiral resonators, have the large optical mode volume needed to reduce the low- to mid-frequency noise down to the thermorefractive noise (TRN) limit29,30. The silicon nitride platform offers low loss from the VIS to SWIR25,31,32,33, and can be used to realize Brillouin lasers and coil resonator stabilization cavities that can operate across octave wavelengths, with application to a wide range of precision applications. However, Brillouin laser stabilization using a common CMOS-compatible platform for both laser and reference cavity, with design flexibility to operate across a more than octave spanning range, has yet to be demonstrated.

Here, we report a class of integrated stabilized Brillouin lasers, capable of operation by design from the VIS to SWIR, fabricated in the CMOS-compatible low-loss Si3N4 integration platform. Over an octave span, we demonstrate orders of magnitude frequency noise reduction from 1 Hz to 10 MHz, resulting in sub-20 Hz fundamental linewidth (FLW) and sub-kHz 1/π integral linewidth (ILW) emission with specific operation at 674 nm for Sr+ ion applications15,34, 698 nm for Sr neutral atom applications2, and 1550 nm for fiber sensing and ultra-low noise microwave applications4,8. The concept and potential applications are illustrated in Fig. 1. Frequency noise and linewidth reduction are achieved in two stages, first using SBS in Si3N4 resonators with the appropriate wavelength pump laser to lower high-frequency offset noise and then PDH locking the SBS laser to a meter-scale Si3N4 coil-resonator reference operating at the same wavelength for low- to mid-frequency offset noise reduction. Using this approach, we reduce the pump laser FLW to Hz-level and the ILW to sub-10 kHz level, across over an octave range. The meter-scale coil resonators are enabled by ultra-low losses and ultra-high quality factors (Q)4. We measure 0.63 dB m−1 and Qi = 94 × 106 at λ = 674 nm, 0.53 dB m−1 and Qi = 110 × 106 at λ = 698 nm, and 0.64 dB m−1 and Qi = 41 × 106 at λ = 1550 nm (Supplementary Information S1). The combination of dilute waveguide modes and coil resonator length provides a large optical mode volume with low TRN floor30, which enables a 10× ILW reduction over the TRN limit of the SBS laser alone. These low losses also enable direct emission SBS lasing with thresholds of 7 mW, 5 mW, and 14.6 mW at 674 nm, 698 nm, and 1550 nm, respectively. In the visible, SBS is used to generate a 14 Hz FLW at 674 nm and a FLW of 7 Hz at 698 nm, while in the SWIR, the SBS FLW is 1.0 Hz at 1550 nm. The meter-scale coil resonator provides an additional order of magnitude ILW reduction for each Brillouin laser, measuring 322 Hz, 630 Hz, and 181 Hz ILW at 674 nm, 698 nm, and 1550 nm, respectively. The coil-resonators also provide short term laser stability with the Allan Deviation (ADEV) measured at 6.5 × 10−13 at 1 ms for 674 nm, 6.0 × 10−13 at 15 ms for 698 nm, and 2.6 × 10−13 at 15 ms for 1550 nm. The ability to reduce the frequency noise and improve stability across the VIS to SWIR, by design, holds promise for integrated precision lasers across a wide range of applications to unlock the potential to move precision experiments out of the laboratory and into the field and portable applications.

Fig. 1
Fig. 1
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Illustration of integrated photonic coil-stabilized Brillouin lasers used for generation ultra-low phase noise and high stability at 674 nm for Sr+ ions, 698 nm for Sr neutral atoms, and 1550 nm for long-distance fiber sensing and ultra-low phase noise RF and microwave generation

Results

We demonstrate operation across over an octave from 674 to 1550 nm of integrated SBS lasers stabilized to integrated coil-resonators using PDH locking. We achieve orders of magnitude frequency noise reduction across the whole frequency range 1 Hz to 10 MHz with close to TRN floor-limited operation. The stabilized laser (Fig. 2a) operates by first locking the pump laser to the integrated SBS resonator, enabling the continuous generation of first Stokes (S1) emission. The Stokes output is optically amplified and frequency tuned using an acousto-optic modulator (AOM) for locking to the coil resonator. In the future, the AOM stage can be removed by direct tuning of the SBS laser35. The S1 output is locked to the integrated coil resonator using a PDH loop and the AOM for frequency noise reduction. The two stages of linewidth narrowing are illustrated in Fig. 2b, c, where Brillouin lasing reduces the high-frequency offset noise and reduces the fundamental (Lorentzian) linewidth of the laser and the second stage lowers the low- to mid-frequency offset noise and reduces the ILW of the laser. The fundamental linewidth is constrained by a combination of SBS laser intracavity power, resonator quality factor (Q), and required operation below the onset of second-order Stokes lasing. The ILW narrowing is limited by the TRN floor of the coil resonator and the gain and bandwidth of the PDH lock.

Fig. 2
Fig. 2
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Coil-stabilized SBS laser and concept of two-stage linewidth narrowing. a Schematic of coil-stabilized SBS experiment. Blue represents the pump laser, orange represents the S1 emission, and green represents the coil-stabilized SBS laser. b Illustration of high-frequency noise reduction of pump laser noise using SBS and low- to mid-frequency noise reduction using coil-stabilization. The TRN limit (black dashed curve), fundamental linewidth (FLW, green dashed line), and integral linewidth (ILW, green shaded area) are shown. c Illustration of linewidth narrowing of the pump laser, S1 emission, and coil-stabilized SBS laser

The coil-resonators and SBS lasers are realized using a weakly confining thin-core, low-loss, high-Q Si3N4 design25,31,36. Here, we demonstrate that the same 40 nm thick nitride waveguide core can be used for both SBS lasers and coil resonators in the visible with mask-only changes in the waveguide width. At 1550 nm, the SBS laser is 40 nm thick for lower loss and threshold, while the coil resonator is 80 nm thick for increased compactness. The benefits of this waveguide configuration and fabrications details can be found in ref. 36. The bend radii are kept above the critical bend radius and the absorption loss is lowered using high-temperature annealing. The TM mode is chosen to reduce sidewall scattering loss31. The SBS resonator waveguide width is 2.3 µm for 674 nm, 2.5 µm for 698 nm, and 11 µm for 1550 nm. The coil resonator waveguide widths are 3 µm for 674 nm and 698 nm, and 6 µm for 1550 nm. The losses are measured using resonator Q factor (Supplementary Information S1) and a calibrated Mach–Zehnder Interferometer (MZI) method (see “Methods”).

The SBS lasers are designed for mW-level threshold operation with integer multiple of the resonator FSR chosen to phase match the Brillouin Stokes shift. The radius of the SBS resonator is 3.73 mm to match the 25.1 GHz Brillouin gain shift at 674 nm20, 3.82 mm to match the 23.3 GHz Brillouin gain shift at 698 nm, and 11.83 mm to match 10.9 GHz Brillouin gain shift at 1550 nm26. The S1 thresholds are measured to be 7 mW, 5 mW, and 15 mW at 674 nm, 698 nm, and 1550 nm26, respectively (Supplementary Information S2). The threshold varies with the propagation loss, resonator bus coupling, and FSR of the cavity relative to the Stokes frequency shift37. Shorter wavelengths have higher propagation loss, resulting in lower Q and higher thresholds for VIS operation. The coupling condition of the cavity affects both the threshold and slope efficiency of the Brillouin lasing. Stronger coupling between the bus waveguide and the resonator yields a higher slope efficiency and a higher threshold. Mismatch of integer multiples of the FSR from the peak Brillouin gain shift for a particular wavelength operation will also increase the S1 threshold.

To generate SBS, the pump laser is PDH locked to the SBS cavity, and the first-order Stokes (S1) is extracted in the counter propagating direction using a circulator. The SBS laser is operated below the second order Stokes (S2) threshold to avoid cascaded emission of SBS, which degrades the S1 fundamental linewidth37. To ensure that second-order Brillouin (S2) lasing does not influence the reported performance, we measure the SBS spectrum with an optical spectrum analyzer with different pump powers. In addition, we track the pump-S1 power relation (Fig. S2), which would exhibit saturation and fundamental linewidth increase if S2 lasing were present. Neither effect is observed over the pump power range studied, confirming that S1 operation remains well below the S2 threshold. The pump sources are external-cavity tunable lasers (ECTLs) at 674 and 698 nm, and a fiber Bragg grating stabilized diode laser at 1550 nm. The pump phase noise output is strongly suppressed since the Brillouin process compresses pump phase diffusion when the phonon decay rate greatly exceeds the optical decay rate and pump linewidth37. There is a transfer of pump intensity38, which we have not accounted for in this work and will be considered in future work. The fundamental linewidths are calculated from the measured white frequency noise (typically above 1 MHz offset), and are reduced to 14 Hz for 674 nm, 7 Hz for 698 nm, and 1 Hz for 1550 nm. This represents a fundamental linewidth reduction from the pump to S1 of 3300X, 280X, and 96X, respectively.

For the visible wavelengths, a 3-m length coil resonator design is used that consists of a waveguide bus connected to two inter-connected 1.5 m spirals, resulting in an optical mode volume that is approximately 125 times that of the 674 nm and 698 nm SBS resonators. At 1550 nm, we use a 4-m-long coil design with a similar layout to the 3 m coils. We use an AOM to frequency shift the SBS laser output for stabilization to the integrated coil resonator cavity (Fig. 3a) with an optical amplifier to compensate for the AOM optical loss. For amplification at 674 nm and 698 nm, we use injection-locked high-power laser diodes (Ushio HL67001DG, HL70021DG) and at 1550 nm we use a commercial EDFA (Fig. 3a, b). In Fig. 3, two main paths are shown, the locking path and measurement path. The locking path modulates the SBS output (S1) using an electro-optic modulator (EOM) for stabilization to the coil resonator. The coil resonator transmission port is then detected for PDH locking. The PDH servo correction is fed back to the AOM to perform frequency correction. The measurement path is used to characterize the frequency noise using an unbalanced fiber MZI and beat note (BN) measurement with a ULE stabilized frequency comb and SHG. The unbalanced fiber MZI (Fig. 3c) is used to measure frequency noise in the ~1 kHz to 10 MHz range (see “Methods”). At low-frequency offsets, 1 Hz to 1 kHz, the fiber MZI environmental fluctuations and noise dominate the laser noise. We use a Vescent fiber frequency comb (model FFC-100) stabilized to a 400,000 finesse ULE cavity (Stable Laser Systems model 6020-4), and frequency-double the comb using SHG to provide a 1 Hz BN reference from 1800 nm down to 600 nm with 100 MHz comb line frequency spacing. The noise is measured by taking the heterodyne BN signal between the laser under test and the nearest comb line (Fig. 3d), followed by a frequency counter as described in “Methods”. The frequency noise data from the heterodyne BN and OFD are stitched together providing laser noise measurements from 1 Hz to 10 MHz. This data is used to extract the FLW and ILW at all wavelengths reported here.

Fig. 3
Fig. 3
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Integrated coil stabilized Brillouin lasers and measurement systems. a SBS laser locked to coil resonator and frequency noise measurement. b Amplifiers. Injection lock to high-power laser diodes for 674 and 698 nm. Commercial Erbium-Doped Fiber Amplifier (EDFA) for 1550 nm. c Frequency noise measurement for >1 kHz with unbalanced fiber MZI as an optical frequency discriminator. LUT light under test. d Frequency noise measurement for 1 Hz to 1 kHz frequency offset using 1 Hz visible light optical frequency comb with heterodyne detection beat notes. SLS stabilized laser system, SCG supercontinuum generation, SHG second-harmonic generation, FC frequency counter. More details in Supplementary Information S3

The resulting stabilized laser noise and linewidth performance are summarized in Fig. 4. We measure a 17 Hz FLW and 322 Hz ILW at 674 nm (Fig. 4a), a 17 Hz FLW and 630 Hz ILW at 698 nm (Fig. 4b), and a 1.0 Hz FLW and 181 Hz ILW at 1550 nm (Fig. 4c). The frequency noise data before the stitch are shown in Supplementary Information S4. These results are for over an octave span with the ILW reduced by 10×–800× compared to the pump laser and the FLW reduced by 96×–2700×. The frequency noise at 674 and 698 nm approaches the TRN limit near 8 kHz frequency offset, while at 1550 nm near 1 kHz frequency offset. Further reduction of the residual excess noise is expected through improvements in the PDH locking scheme at higher frequency offsets and enhanced acoustic and vibrational isolation of the reference coil resonator at lower frequency offsets. We note that the fundamental linewidth is slightly increased from S1 due to the added noise of the amplifiers. The ADEV is calculated from the frequency noise data (Fig. 4d) with a minimum of 6.5 × 10−13 at 1 ms for 674 nm, 6.0 × 10−13 at 15 ms for 698 nm, and 2.6 × 10−13 at 15 ms for 1550 nm. The simulated TRN-limited integral linewidth of the coil resonators is below 100 Hz, which represents the achievable ILW for all lasers given optimal PDH lock performance.

Fig. 4
Fig. 4
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Frequency noise of the integrated coil-stabilized Brillouin lasers. Comparison of the frequency noise of the pump laser, the S1 tone of SBS, and the coil stabilized laser at a 674 nm, b 698 nm, and c 1550 nm. The pump and S1 frequency noise are measured with OFD. The coil-stabilized laser frequency noise is stitched between OFD and heterodyne detection to an ultra-stable reference laser. The stitching points are marked in the plots with vertical dashed lines. The green horizontal dashed lines show the white noise floor determining the fundamental linewidth. The shaded areas show the integral of the frequency noise that determines the integral linewidth of the laser. d Allan deviation (ADEV) of the coil stabilized Brillouin laser at 674 nm, 698 nm, and 1550 nm. The dashed lines label the minimum of the ADEV

Discussion

We demonstrate silicon nitride integrated coil resonator stabilized Brillouin laser designs that are capable of operating over an octave span from the VIS to SWIR and report record-low linewidths and frequency noise from 1 Hz to 10 MHz with close to TRN-limited performance over this wide wavelength range. This dual-stage laser design is demonstrated at key wavelengths in the visible for the strontium atomic species quantum applications and in the SWIR for fiber sensing and ultra-low phase noise microwave and RF generation. Compared with our previous demonstration of Brillouin lasing in similar on-chip cavities, the fundamental linewidth at 674 nm is improved by more than an order of magnitude, from 269.720 to 17 Hz. At 1550 nm, the achieved fundamental linewidth of 1.0 Hz is comparable to the earlier 0.7 Hz result26. Furthermore, the ILW is reduced from the 1–10 kHz range of a standalone Brillouin laser to the sub-kHz regime through coil stabilization. In principle, a single high-bandwidth cavity lock could suppress noise across all offset frequencies, but achieving MHz-level feedback with conventional optoelectronic loops is extremely challenging due to delay and parasitic limitations. In contrast, the SBS process intrinsically suppresses high-frequency noise through photon–phonon dynamics, while the coil resonator PDH lock provides mid- and low-frequency stabilization. Together, this two-stage approach achieves broadband noise reduction, with the ultimate limit set by TRN of the optical cavities. With further optimization of the coil resonator PDH lock39 and improved acoustic isolation of the integrated laser and coil the linewidths can be reduced to the coil TRN limited 50 Hz, 63 Hz, and 6 Hz ILW at 674, 698, and 1550 nm, respectively. The fundamental linewidth and optical power can be further reduced through improved design of the SBS laser. For example, second-order Stokes (S2) suppression40,41,42 or an increase in the SBS cavity length43. Since the Brillouin laser and coil resonator are fabricated on the same silicon nitride platform using the same process flow, the laser and cavity can be integrated on the same chip and combined with other components, for example, a 50/50 splitter, S1 optical filter, and pump lasers21,44.

Recent advances in integrated laser stabilization have established a range of performance benchmarks, including Hz-level fundamental linewidths, kHz-level and sub-kHz ILWs across integrated platforms such as self-injection locked (SIL) lasers21,45, ECTLs46,47, and extended distributed Bragg grating (EDBR) lasers48. Our results add to this design phase space by demonstrating that coil-stabilized SBS lasers can achieve both ultra-narrow fundamental linewidths and ILWs well below 1 kHz, while extending operation into the visible. Compared with SIL lasers, the coil-stabilized SBS laser provides a larger tuning range and higher stability over the larger tuning range, while SIL lasers are inherently free of servo-induced noise bumps. We estimate the effective tuning range of the Brillouin laser by considering the pump wavelength detuning at which the Brillouin gain decreases by half. This yields values of ~3.5 nm at 674 nm, ~3.5 nm at 698 nm, and ~17.7 nm at 1550 nm for the resonators studied here, assuming the range is not constrained by the pump laser’s own mode-hop-free operation or by the tuning capability of the SBS cavity. In practice, the achievable range will also likely be limited by these factors, but the estimates highlight the potential for wide and stable tunability in the SBS platform. Compared with ECTL lasers, SBS lasers exhibit a lower fundamental linewidth and higher noise suppression at large offset frequencies, which is advantageous for applications requiring higher Rabi frequencies. On the other hand, since SBS lasers are still pumped by an ECTL, improvements in the pump laser’s mode-hop-free tuning range and low-offset frequency noise would further enhance the performance of the coil-stabilized SBS laser. Taken together, these attributes suggest that SBS-mediated stabilization is a strong candidate to become the leading integrated solution for clock-grade, quantum, and sensing applications.

The integrated SBS laser and coil resonators can be readily implemented at many wavelengths within the Si3N4 transparency window31. The wavelength-dependent design includes two main aspects. The first is the waveguide design, including width, minimum bend radius, and ring-bus coupling gap, which are adjusted at the mask level to optimize performance at different wavelengths. The second is engineering the resonator FSR to match the Brillouin shift at the target wavelength, achieved by setting the resonator radius in the mask design. Together, these parameters enable the realization of SBS lasers at the desired wavelength with the required performance. Demonstrations at 674 nm and 698 nm specifically target transitions relevant to strontium trapped ions and neutral atoms, making this approach suitable for optical clocks and quantum information processing. The narrow laser linewidth provides low phase noise at key frequency offsets, which is significant to the fidelity of qubit operations and stability of atomic clocks15,34. This approach can be used to address a broader set of wavelengths of interest to quantum applications, including the important 780 nm for rubidium. The current results in the visible demonstrate the potential to achieve lower ILWs compared to prior SIL-only approaches 780 nm21. Future work will also extend ADEV measurements to longer averaging times relevant for optical clocks (>1000 s), including assessments of long-term drift and Allan deviations that are expected to follow \(1/\sqrt{\tau }\) scaling, together with consideration of systematics in the full physics package. The performance of fiber interferometric sensing improves with decreased phase noise8,9 and the microwave phase noise in optical frequency division approaches can be reduced using low noise stabilized lasers4,6,7.

Looking ahead, this coil-stabilized SBS laser design, fabricated in the versatile ultra-low-loss silicon nitride platform, provides a CMOS foundry-compatible way to integrate a wide range of precision technologies at the chip scale. To integrate both SBS and coil cavity on the same chip, an integrated frequency shifting component or direct modulation of the SBS cavity is required to replace the AOM in the system, such as PZT or AlN modulated cavities. Because the pump is PDH locked to the SBS cavity, tuning the cavity directly shifts the SBS frequency, with a feedback bandwidth up to ~10 MHz using PZT actuation. To avoid loop interaction, the lock bandwidths are separated in frequency, ensuring stable operation of both servos. The SBS light does not carry the pump-laser PDH modulation, since the sidebands contain much less optical power and their lasing thresholds rise rapidly with detuning from resonance, preventing them from reaching the Brillouin threshold. As a result, the first-stage modulation does not interfere with the second-stage lock, allowing both to operate stably and supporting future full integration of both stage locks. The 1550 nm SBS cavity can be implemented with an 80 nm thickness, ensuring compatibility with the coil resonator and allowing a more compact design, with a slight trade-off in propagation loss and linewidth. By combining on-chip SBS and coil resonators with integrated components such as ECTLs44,46,49, piezoelectric (PZT or AlN) modulators50,51 AOMs52,53 and ion or atom traps54,55,56 a complete optical system-on-chip can be realized. These results unlock the potential for compact atomic clocks, scalable quantum computing architectures, high-resolution spectroscopy, low-phase-noise mm-wave generation, and field-deployable sensors.

Methods

Fabrication process

The fabrication starts with 15 µm thermally grown silicon dioxide on top of the silicon substrate. A stoichiometric silicon nitride film is then deposited with low-pressure chemical vapor deposition (LPCVD). The waveguide is patterned by a 248 nm DUV stepper and etched by inductively coupled plasma reactive ion etch with CF4/CHF3/O2 gas. The upper cladding is 6 µm silicon dioxide deposited with tetraethylorthosilicate (TEOS)-based plasma enhanced chemical vapor deposition (PECVD) and annealed to mitigate scattering and absorption losses.

Quality factor measurements and calculation

The power of a frequency-detuning laser is split into two fractions. One fraction is sent through an unbalanced fiber MZI with a calibrated FSR as a frequency reference. The other fraction is sent through the tested resonator. Both power transmissions of the fiber MZI and the tested resonator are synchronized and recorded with an oscilloscope. The loss and Q of the resonance are calculated by fitting the transmission spectrum to waveguide resonator theory. The measured frequency detuning is calibrated to the FSR of the fiber MZI.

Optical frequency discrimination and beat note measurements of frequency noise

Frequency noise is measured either by optical frequency discrimination (OFD) with a fiber MZI or BN with a stabilized laser system (SLS) reference. The unbalanced fiber MZI is first calibrated for FSR frequency. We send the laser to be tested through the fiber MZI and measure the difference in output optical power with balanced photodetectors. Then, we ramp the phase shift on one arm of the fiber MZI to get peak-to-peak voltage of the photodetector output. With the calibrated FSR and measured peak-to-peak voltage, the power output change corresponds to an optical frequency shift around the quadrature point. While taking a measurement, we trigger the measurement around the quadrature point and sample with different rates for different offset ranges. We average the data over several measurements and stitch different sampling rate traces for the full range frequency noise data.

For low-offset frequency noise, which is limited by the fiber MZI vibration and acoustic noises, we measure the BN between the tested laser and our frequency comb locked to the SLS. The comb operates in the C-band and is frequency-doubled to reach the visible wavelength range. We mix the two lasers and measure the BN signal with a frequency counter. The stability of the SLS allows us to measure the frequency noise in offsets of 1–1000 Hz. Due to the limited optical power of the comb and the nonlinear efficiency of the frequency doubling, at 674 and 698 nm, we phase lock the BN signal to a voltage-controlled oscillator to improve the signal-to-noise ratio for the frequency counter.